Intraosseous device couplers, drivers, kits, and methods

ABSTRACT

This disclosure includes various embodiments of couplers for coupling intraosseous (IO) devices and drivers, and various embodiments of drivers and kits.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. patent application Ser. No.13/835,383, filed on Mar. 15, 2013, and entitled “Intraosseous DeviceCouplers, Drivers, Kits, and Methods,” the content of which is hereinincorporated by reference in its entirety.

BACKGROUND 1. Field of the Invention

The present invention relates generally to intraosseous (IO) access and,more particularly, but not by way of limitation, to couplers, drivers,IO devices (e.g., needle sets), and methods that can be used tofacilitate IO access (e.g., to obtain bone marrow from the bone of apatient for biopsy and/or transplantation).

2. Description of Related Art

Examples of couplers, drivers, IO devices, and kits are disclosed, forexample, in International Patent Application No. PCT/US2007/078207(published as WO 2008/033874).

SUMMARY

This disclosure includes embodiments of couplers, drivers, IO devices,and kits.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end configured to be coupled in fixed relation toa driveshaft of a driver having a housing such that at least a portionof the hub is disposed outside the housing of the driver; where thefirst end of the drive hub includes female threads configured to becoupled to an intraosseous (IO) device. In some embodiments, the secondend of the drive hub comprises female threads configured to be coupledto the driveshaft of a driver. In some embodiments, the female threadsin the second end of the drive hub are configured to tighten if a driverrotates the drive hub and an IO device coupled to the drive hub in aclockwise direction.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end including a recess configured to receive adriveshaft of a driver; where the first end of the drive hub isconfigured to be coupled to an intraosseous (IO) device to resistrotation of the IO device relative to the drive hub; and where thesecond end of the drive hub is configured such that if a driveshaft isinserted into the recess, an interference fit between the drive hub andthe driveshaft will resist rotation of the drive hub relative to thedriveshaft. In some embodiments, the recess has a circularcross-sectional shape. In some embodiments, the recess is defined by acylindrical wall. In some embodiments, the second end further includes asecond recess surrounding at least a portion of the cylindrical wall. Insome embodiments, the second end of the hub includes a plurality of tabsextending into the recess, the plurality of tabs being configured todeform if the driveshaft is inserted into the recess. In someembodiments, the plurality of tabs each has a triangular cross-sectionalshape. In some embodiments, the recess has a circular central portionand one or more peripheral portions extending outwardly from thecircular central portion. In some embodiments, the plurality of tabsextend into the peripheral portions of the openings. In someembodiments, the first end of the drive hub includes a recess and isconfigured such that if a hub of an IO device is inserted into therecess, an interference fit between the drive hub and the IO device willresist rotation of the IO device relative to the drive hub.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end configured to be coupled in fixed relation toa driveshaft of a driver; where the first end of the drive hub has arecess configured to receive a portion of an intraosseous (IO) device;and where the first end of the drive hub is configured such that if aportion of the IO device is inserted into the recess, an interferencefit between the drive hub and the IO device will resist rotation of theIO device relative to the drive hub. In some embodiments, the recess hasa circular cross-sectional shape. In some embodiments, the recess isdefined by a cylindrical wall. In some embodiments, the first endfurther includes a second recess surrounding at least a portion of thecylindrical wall. In some embodiments, the first end of the hub includesa plurality of tabs extending into the recess, the plurality of tabsconfigured to deform if the driveshaft is inserted into the recess. Insome embodiments, the plurality of tabs each has a triangularcross-sectional shape. In some embodiments, the recess has a circularcentral portion and one or more peripheral portions extending outwardlyfrom the circular central portion. In some embodiments, the plurality oftabs extend into the peripheral portions of the openings. In someembodiments, the second end of the drive hub includes a recess and isconfigured such that if the driveshaft is inserted into the recess, aninterference fit between the drive hub and the driveshaft will resistrotation of the drive hub relative to the driveshaft.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end including a recess configured to receive adriveshaft of a driver; and an adhesive disposed in the recess andconfigured to adhere to a driveshaft inserted into the recess; where thefirst end of the drive hub is configured to be coupled to anintraosseous (IO) device to resist rotation of the IO device relative tothe drive hub; and where the recess has a cross-sectional shapecorresponding to the cross-sectional shape of the driveshaft such thatif the driveshaft is inserted into the second recess, the drive hub willresist rotating relative to the driveshaft. In some embodiments, therecess has a non-circular cross-sectional shape. In some embodiments,the first end of the drive hub includes a second recess configured toreceive a hub of an IO device; the second recess has a cross-sectionalshape corresponding to a cross-sectional shape of the hub of the IOdevice such that if the portion of the IO device is inserted into therecess, the drive hub will resist rotation of the IO device relative tothe drive hub; and the coupler further comprises a second adhesivedisposed in the second recess and configured to adhere to an IO deviceinserted into the second recess.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end configured to be coupled in fixed relation toa driveshaft of a driver; where the first end of the drive hub has arecess configured to receive a portion of an intraosseous (IO) device;and where the recess has a cross-sectional shape corresponding to across-sectional shape of the portion of the IO device such that if theportion of the IO device is inserted into the recess, the drive hub willresist rotation of the IO device relative to the drive hub.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end including a recess configured to receive adriveshaft of a driver; and a resilient clip biased toward an axis ofrotation of the drive hub; where the first end of the drive hub isconfigured to be coupled to an intraosseous (IO) device to resistrotation of the IO device relative to the drive hub; and where therecess has a cross-sectional shape corresponding to a cross-sectionalshape of the driveshaft such that if the driveshaft is inserted into therecess, the drive hub will resist rotating relative to the driveshaft.In some embodiments, the couplers comprise a hollow sleeve configured tobe disposed around the recess such that a driveshaft inserted into therecess will be disposed in the hollow sleeve; where the resilient clipis unitary with the hollow sleeve. In some embodiments, the hollowsleeve and resilient clip comprise a single piece of sheet metal. Insome embodiments, the distal end of the driveshaft has a non-circularcross-section.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end including a recess configured to receive adriveshaft of a driver, the drive hub having a sidewall with at leastone opening extending through the sidewall in communication with therecess, the at least one opening having an inner cross-sectional area atthe recess that is smaller than an outer cross-sectional area spacedapart from the inner cross-sectional area; at least one ball movablydisposed in the at least one opening in the drive hub; a resilientc-clip disposed around the drive hub such that the c-clip biases the atleast one ball toward a rotational axis of the drive hub; where thefirst end of the drive hub is configured to be coupled to anintraosseous (IO) device to resist rotation of the IO device relative tothe drive hub; and where the second end of the drive hub is configuredsuch that if a driveshaft having at least one detent is inserted intothe recess, the c-clip will (i) allow the at least one ball to move awayfrom the rotational axis of the drive hub until the at least one detentaligns with the at least one ball, and (ii) press the at least one ballinto the at least one detent when the at least one detent is alignedwith the at least one ball to resist removal of the driveshaft from therecess. In some embodiments, the driveshaft and the recess each has anon-circular cross-sectional shape. In some embodiments, the drive hubhas a circular outer cross-sectional shape. In some embodiments, thefirst end of the drive hub includes a second recess configured toreceive a hub of an IO device, and the drive hub has at least one secondopening extending through the sidewall in communication with the secondrecess, the at least one second opening having an inner cross-sectionalarea at the second recess that is smaller than an outer cross-sectionalarea spaced apart from the inner cross-sectional area; the couplerfurther comprising: at least one second ball movably disposed in the atleast one second opening in the drive hub; a second resilient c-clipdisposed around the drive hub such that the c-clip biases the at leastone second ball toward a rotational axis of the drive hub; where thefirst end of the drive hub is configured such that if a hub of an IOdevice having at least one second detent is inserted into the recess,the second c-clip will (i) allow the at least one ball to move away fromthe rotational axis of the drive hub until the at least one seconddetent aligns with the at least one second ball, and (ii) press the atleast one second ball into the at least one second detent when the atleast one second detent is aligned with the at least one second ball toresist removal of the IO device from the recess.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end configured to be coupled in fixed relation toa driveshaft of a driver, the first end including a recess configured toreceive a hub of an IO device, the drive hub having a sidewall with atleast one opening extending through the sidewall in communication withthe recess, the at least one opening having an inner cross-sectionalarea at the recess that is smaller than an outer cross-sectional areaspaced apart from the inner cross-sectional area; at least one ballmovably disposed in the at least one opening in the drive hub; aresilient c-clip disposed around the drive hub such that the c-clipbiases the at least one ball toward a rotational axis of the drive hub;where the second end of the drive hub is configured such that if a hubof an intraosseous (IO) device having at least one detent is insertedinto the recess, the c-clip will (i) allow the at least one ball to moveaway from the rotational axis of the drive hub until the at least onedetent aligns with the at least one ball, and (ii) press the at leastone ball into the at least one detent when the at least one detent isaligned with the at least one ball to resist removal of the driveshaftfrom the recess. In some embodiments, the hub of the IO device and therecess each has a non-circular cross-sectional shape. In someembodiments, the drive hub has a circular outer cross-sectional shape.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end configured to be coupled in fixed relation toa driveshaft of a driver, the first end including a recess configured toreceive a hub of an IO device, the drive hub having a sidewall with atleast one opening extending through the sidewall in communication withthe recess, the at least one opening having an inner cross-sectionalarea at the recess that is smaller than an outer cross-sectional areaspaced apart from the inner cross-sectional area; at least one ballmovably disposed in the at least one opening in the drive hub; a collarmovably disposed around the drive hub and having an interior surfacedefining at least one detent adjacent the drive hub; where the collar ismovable between (i) a first position in which the at least one detent ofthe collar is aligned with the at least one opening such that the atleast one ball can move away from the rotational axis of the drive hubto permit a hub of an intraosseous (IO) device having a detent to beinserted into or removed from the recess, and (ii) a second position inwhich the at least one detent of the collar is not aligned with the atleast one opening such that if a hub of an IO device having at least onedetent is disposed in the recess such that the at least one detent ofthe hub is aligned with the opening, the IO device is prevented frombeing removed from the recess. In some embodiments, the collar is biasedtoward the second position. In some embodiments, the hub of the IOdevice and the recess each has a non-circular cross-sectional shape. Insome embodiments, the second end of the drive hub includes a secondrecess configured to receive a driveshaft of a driver, and the drive hubhas at least one second opening extending through the sidewall incommunication with the second recess, the at least one second openinghaving an inner cross-sectional area at the second recess that issmaller than an outer cross-sectional area spaced apart from the innercross-sectional area; the coupler further comprising at least one secondball movably disposed in the at least one second opening in the drivehub; a second collar movably disposed around the drive hub and having aninterior surface defining at least one second detent adjacent the drivehub; where the second collar is movable between (i) a first position inwhich the at least one second detent of the second collar is alignedwith the at least one second opening such that the at least one secondball can move away from the rotational axis of the drive hub to permit adriveshaft having a detent to be inserted into or removed from thesecond recess, and (ii) a second position in which the at least onesecond detent of the collar is not aligned with the at least one secondopening such that if driveshaft of a driver having at least one seconddetent is disposed in the second recess such that the at least onesecond detent is aligned with the opening, the driveshaft is preventedfrom being removed from the recess.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end including a recess configured to receive adriveshaft of a driver, the drive hub having a sidewall with at leastone opening extending through the sidewall in communication with therecess; at least one set screw with a spring-loaded ball, the at leastone set screw disposed in the at least one opening in the drive hub suchthat the ball is biased in a direction toward an axis of rotation of thedrive hub; where the first end of the drive hub is configured to becoupled to an intraosseous (IO) device to resist rotation of the IOdevice relative to the drive hub; and where the second end of the drivehub is configured such that if a driveshaft having at least one detentis inserted into the recess (i) the spring-loaded ball of the at leastone set screw will move away from the rotational axis of the drive hubuntil the at least one detent aligns with the at least one ball, and(ii) the spring-loaded ball of the at least one set screw will move intothe at least one detent when the at least one detent is aligned with theat least one ball to resist removal of the driveshaft from the recess.In some embodiments, the driveshaft and the recess each has anon-circular cross-sectional shape. In some embodiments, where the firstend of the drive hub includes a second recess configured to receive ahub of an IO device, and the drive hub has at least one second openingextending through the sidewall in communication with the second recess;the coupler further comprising at least one second set screw with aspring-loaded ball, the at least one second set screw disposed in the atleast one second opening in the drive hub such that the ball is biasedin a direction toward an axis of rotation of the drive hub; where thesecond end of the drive hub is configured such that if a hub of an IOdevice having at least one second detent is inserted into the recess (i)the spring-loaded ball of the at least one second set screw will moveaway from the rotational axis of the drive hub until the at least onesecond detent aligns with the at least one ball, and (ii) thespring-loaded ball of the at least one second set screw will move intothe at least one second detent when the at least one detent is alignedwith the at least one second ball to resist removal of the IO devicefrom the recess.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end configured to be coupled in fixed relation toa driveshaft of a driver, the first end including a recess configured toreceive a hub of an intraosseous (IO) device, the drive hub having asidewall with at least one opening extending through the sidewall incommunication with the recess; at least one set screw with aspring-loaded ball, the at least one set screw disposed in the at leastone opening in the drive hub such that the ball is biased in a directiontoward an axis of rotation of the drive hub; where the first end of thedrive hub is configured such that if a hub of an IO device having atleast one detent is inserted into the recess (i) the spring-loaded ballof the at least one set screw will move away from the rotational axis ofthe drive hub until the at least one detent aligns with the at least oneball, and (ii) the spring-loaded ball of the at least one set screw willmove into the at least one detent when the at least one detent isaligned with the at least one ball to resist removal of the IO devicefrom the recess. In some embodiments, the hub of the IO device and therecess each has a non-circular cross-sectional shape.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end including a recess configured to receive adriveshaft of a driver, the drive hub having a sidewall with an openingextending through the sidewall in communication with the recess; a screwhaving an enlarged head and a threaded shaft with a distal end, thescrew threaded into the opening with the distal end facing in adirection toward an axis of rotation of the drive hub; where the firstend of the drive hub is configured to be coupled to an intraosseous (IO)device to resist rotation of the IO device relative to the drive hub;and where the screw is rotatable between (i) a first position in whichthe distal end does not extend into the recess to permit a driveshafthaving a detent to be inserted into or removed from the recess, and (ii)a second position in which the distal end extends into the recess suchthat if a driveshaft having a detent is disposed in the recess such thatthe detent of the driveshaft is aligned with the opening, the driveshaftis prevented from being removed from the recess. In some embodiments,the driveshaft and the recess each has a non-circular cross-sectionalshape. In some embodiments, the first end of the drive hub includes asecond recess configured to receive a hub of an IO device, and the drivehub has a second opening extending through the sidewall in communicationwith the second recess; the coupler further comprising a second screwhaving an enlarged head and a threaded shaft with a distal end, thescrew threaded into the second opening with the distal end facing in adirection toward an axis of rotation of the drive hub; where the secondscrew is rotatable between (i) a first position in which the distal enddoes not extend into the second recess to permit a hub of an IO devicehaving a detent to be inserted into or removed from the recess, and (ii)a second position in which the distal end extends into the second recesssuch that if a hub of an IO device having a detent is disposed in therecess such that the detent of the hub is aligned with the opening, theIO device is prevented from being removed from the recess.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end configured to be coupled in fixed relation toa driveshaft of a driver, the first end including a recess configured toreceive a hub of an intraosseous (IO) device, the drive hub having asidewall with an opening extending through the sidewall in communicationwith the recess; a screw having an enlarged head and a threaded shaftwith a distal end, the screw threaded into the opening with the distalend facing in a direction toward an axis of rotation of the drive hub;where the screw is rotatable between (i) a first position in which thedistal end does not extend into the recess to permit a hub of an IOdevice having a detent to be inserted into or removed from the recess,and (ii) a second position in which the distal end extends into therecess such that if a hub of an IO device having a detent is disposed inthe recess such that the detent of the hub is aligned with the opening,the IO device is prevented from being removed from the recess.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end including a recess configured to receive adriveshaft of a driver, the drive hub having a sidewall with an openingextending through the sidewall in communication with the recess; a pinhaving a distal end configured to be inserted into the opening such thatthe pin extends across a majority of a width of the recess; where thefirst end of the drive hub is configured to be coupled to anintraosseous (IO) device to resist rotation of the IO device relative tothe drive hub; and where the pin is movable between (i) a first positionin which the distal end does not extend into the recess to permit adriveshaft having a transverse passageway to be inserted into or removedfrom the recess, and (ii) a second position in which the pin extendsinto and across a majority of the recess such that if a driveshafthaving a transverse passageway is disposed in the recess such that thetransverse passageway is aligned with the opening, the pin extends intothe transverse passageway to prevent the driveshaft from being removedfrom the recess. In some embodiments, the driveshaft and the recess eachhas a non-circular cross-sectional shape. In some embodiments, the firstend of the drive hub includes a second recess configured to receive ahub of an IO device, and the drive hub has a second opening extendingthrough the sidewall in communication with the second recess; thecoupler further comprising a second pin having a distal end configuredto be inserted into the second opening such that the pin extends acrossa majority of a width of the second recess; where the second pin ismovable between (i) a first position in which the distal end does notextend into the second recess to permit a driveshaft having a transversepassageway to be inserted into or removed from the second recess, and(ii) a second position in which the second pin extends into and across amajority of the second recess such that if a hub of an IO device havinga transverse passageway is disposed in the second recess such that thetransverse passageway is aligned with the opening, the pin extends intothe transverse passageway to prevent the IO device from being removedfrom the second recess.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end configured to be coupled in fixed relation toa driveshaft of a driver, the first end including a recess configured toreceive a hub of an intraosseous (IO) device, the drive hub having asidewall with an opening extending through the sidewall in communicationwith the recess; a pin having a distal end configured to be insertedinto the opening such that the pin extends across a majority of a widthof the recess; where the pin is movable between (i) a first position inwhich the distal end does not extend into the recess to permit a hub ofan IO device having a transverse passageway to be inserted into orremoved from the recess, and (ii) a second position in which the pinextends into and across a majority of the recess such that if a hub ofan IO device having a transverse passageway is disposed in the recesssuch that the transverse passageway is aligned with the opening, the pinextends into the transverse passageway to prevent the IO device frombeing removed from the recess.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end configured to be coupled in fixed relation toa driveshaft of a driver; a resilient clamp having a substantiallycircular interior, the clamp configured to be movable between (i) acontracted position in which the interior has a first transversedimension, and (ii) an expanded position in which the interior has asecond transverse dimension that is larger than the first transversedimension, where the resilient clamp is biased toward the contractedposition; where the first end of the drive hub has a transversedimension that is larger than the first transverse dimension of theclamp, and that is larger than a transverse dimension of the driveshaft;where the first end of the drive hub is configured to abut anintraosseous (IO) device such that the clamp can be disposed around thedrive hub and the IO device to resist separation of the IO device fromto the drive hub. In some embodiments, the drive hub has a cross-sectionwith a circular central portion and a projection extending from thecentral portion in a direction away from a rotational axis of the drivehub. In some embodiments, the drive hub is not configured to receive aportion of the IO device. In some embodiments, the drive hub isconfigured to abut an IO device such that the clamp can be disposedaround and in contact with the drive hub and the IO device to resistseparation of the IO device from the drive hub. In some embodiments, thefirst end of the drive hub includes a sidewall defining a recessconfigured to receive a hub of the IO device, the sidewall having atleast one slot extending through the sidewall in communication with therecess in the first end. In some embodiments, the second end of thedrive hub includes a sidewall defining a recess configured to receive adriveshaft of a driver, the sidewall having at least one slot extendingthrough the sidewall in communication with the recess in the second end,the coupler further comprising a second resilient clamp having asubstantially circular interior, the second clamp configured to bemovable between (i) a contracted position in which the interior has afirst transverse dimension, and (ii) an expanded position in which theinterior has a second transverse dimension that is larger than the firsttransverse dimension, where the second resilient clamp is biased towardthe contracted position; where the second end of the drive hub has atransverse dimension that is larger than the first transverse dimensionof the clamp, and that is larger than a transverse dimension of thedriveshaft; where the recess in the second end of the drive hub isconfigured to receive a driveshaft of a driver such that the clamp canbe disposed around the drive hub and the driveshaft to resist separationof the drive hub from the driveshaft.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end including a sidewall defining a recessconfigured to receive a driveshaft of a driver, the sidewall having atleast one slot extending through the sidewall in communication with therecess in the second end; a resilient clamp having a substantiallycircular interior, the clamp configured to be movable between (i) acontracted position in which the interior has a first transversedimension, and (ii) an expanded position in which the interior has asecond transverse dimension that is larger than the first transversedimension, where the resilient clamp is biased toward the contractedposition; where the second end of the drive hub has a transversedimension that is larger than the first transverse dimension of theclamp; and where the recess is configured to receive a driveshaft of adriver such that the clamp can be disposed around the drive hub and thedriveshaft to resist separation of the drive hub from the driveshaft. Insome embodiments, the recess is configured to receive a driveshaft of adriver such that the clamp can be disposed around and in contact withthe drive hub and the driveshaft to resist separation of the drive hubfrom the driveshaft.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end configured to be coupled in fixed relation toa driveshaft of a driver, the first end including a plurality of movableprongs configured to grasp a hub of an intraosseous (IO) device; acollar movably disposed around the drive hub; where the collar ismovable between (i) a first position in which the plurality of prongscan move away from the rotational axis of the drive hub to permit an IOdevice to be inserted into or removed from the plurality of prongs, and(ii) a second position in which the collar constrains the plurality ofprongs such that if a hub of an IO device is disposed between theplurality of prongs, the prongs resist removal of the IO device from theplurality of prongs. In some embodiments, the collar is biased towardthe second position. In some embodiments, the second end of the drivehub includes including a second plurality of movable prongs configuredto grasp a driveshaft of a driver, the coupler further comprising asecond collar movably disposed around the drive hub; where the secondcollar is movable between (i) a first position in which the secondplurality of prongs can move away from the rotational axis of the drivehub to permit a driveshaft to be inserted into or removed from thesecond plurality of prongs, and (ii) a second position in which thesecond collar constrains the second plurality of prongs such that if ahub of an IO device is disposed between the second plurality of prongs,the second plurality of prongs resists removal of IO device from thesecond plurality of prongs.

Some embodiments of the present couplers comprise a drive hub having afirst end and a second end including a recess configured to receive adriveshaft of a driver, the recess having a proximal end and a distalend; a magnetic ring disposed around a perimeter of the recess betweenthe proximal end of the recess and the distal end of the recess; wherethe first end of the drive hub is configured to be coupled to anintraosseous (IO) device to resist rotation of the IO device relative tothe drive hub. In some embodiments, the recess has a non-circularcross-sectional shape. In some embodiments, the magnetic ring defines astep within the recess. In some embodiments, the first end of the drivehub includes a second recess configured to receive a driveshaft of adriver, the recess having a proximal end and a distal end, the couplerfurther comprising a second magnetic ring disposed around a perimeter ofthe second recess between the proximal end of the second recess and thedistal end of the second recess. In some embodiments, the recess has anon-circular cross-sectional shape. In some embodiments, the secondmagnetic ring defines a step within the second recess. In someembodiments, the second end of the drive hub comprises a flangeextending outwardly relative to an axis of rotation of the drive hub.

Some embodiments of the present drivers comprise a housing; a powersource; a driveshaft coupled to the power source such that the powersource can cause the driveshaft to rotate; and a coupler of having anyof the disclosed features or characteristics, where the drive hub isconfigured to be coupled to the driveshaft such that at least a portionof the drive hub is disposed outside the housing. In some embodiments, aportion of the driveshaft is tapered. In some embodiments, the drive hubis unitary with the driveshaft. In some embodiments, the power sourcecomprises a spring. In some embodiments, the drivers further comprise anelectric motor coupled to the driveshaft and the power source. In someembodiments, the driveshaft has a distal end including male threadscorresponding to the female threads in the second end of the drive hub.In some embodiments, the driveshaft has a distal end with a non-circularcross-sectional shape. In some embodiments, the distal end of thedriveshaft comprises one or more projections extending outward relativeto an axis of rotation of the driveshaft. In some embodiments, thedistal end of the driveshaft has a cross-section that is a differentshape than a cross-section of the recess in the second end of the drivehub. In some embodiments, the driveshaft comprises a cross-section witha circular central portion and a projection extending from the centralportion in a direction away from a rotational axis of the driveshaft. Insome embodiments, the drivers comprise an element comprising at leastone of a magnet and a magnetically-attractive material, the elementcoupled to the driveshaft and spaced apart from the distal end of thedriveshaft; where the element of the driver is configured tomagnetically couple to the magnetic ring of the coupler if thedriveshaft is inserted into the recess in the second end of the coupler.In some embodiments, the element is disposed within the driveshaft. Insome embodiments, the element comprises a ring disposed around thedriveshaft.

Some embodiments of the present drivers comprise a housing having a bodyportion and a shroud portion, the body portion having a sidewalldefining a distal end, and the shroud portion having a cylindricalsidewall extending from the distal end of the body portion, the shroudportion having an open distal end; a power source; and a driveshaftdisposed in the body portion of the housing and coupled to the powersource such that the power source can cause the driveshaft to rotate,the driveshaft having a distal end extending from the body portion andinto the shroud portion; where the driver is configured to be coupled toan IO device having a hub with a recess sized to receive the distal endof the driveshaft, such that the distal end of the driveshaft extendsinto the recess and the hub of the IO device is at least partiallydisposed in the shroud portion of the housing. In some embodiments, thedrivers comprise a plate having an opening, the plate disposed in theshroud portion of the housing with the driveshaft aligned with theopening such that the plate is movable within the shroud along a lengthof the driveshaft; and a spring disposed between the plate and thedistal end of the body portion of the housing such that the springbiases the plate in a direction toward the open end of the shroudportion. In some embodiments, the shroud portion comprises a lipextending inward toward the driveshaft and configured to prevent theplate from exiting the shroud portion. In some embodiments, the shroudportion of the housing has one or more projections extending in adirection away from the driveshaft. In some embodiments, the one or moreprojections comprise two projections extending in opposite directions.In some embodiments, the shroud portion comprises one or more resilientportions and one or more substantially rigid portions, and the one ormore projections extend from the one or more resilient portions suchthat the one or more projections are movable relative to the driveshaft.In some embodiments, the shroud portion has two elongated grooves in anouter surface of the cylindrical sidewall, the two elongated groovesextending in a direction that is substantially perpendicular torotational axis of the driveshaft.

Some embodiments of the present kits comprise a driver having any of thedisclosed features or characteristics and an intraosseous (IO) devicecomprising a first hub having a cannula coupled in fixed relation to thehub, the cannula having a distal end extending from a distal of the hub;where the IO device is configured to be coupled to the first end of thedrive hub of the coupler. As described below, any couplers having thedisclosed features or characteristics may be included. In someembodiments, the IO device is configured to be coupled to the first endof the drive hub such that the drive hub contacts the first hub of theIO device. In some embodiments, the IO device further comprises a secondhub configured to be coupled to the first hub. In some embodiments, thesecond hub has a trocar with a distal end extending from the second hub,and the second hub is configured to be coupled to the first hub suchthat the trocar extends through a longitudinal passage of the trocar. Insome embodiments, the IO device is configured to be coupled to the firstend of the drive hub of the coupler such that the drive hub contacts thesecond hub of the IO device. In some embodiments, the second hub of theIO device is unitary with the drive hub of the coupler. In someembodiments, the second hub of the IO device comprises male threadscorresponding to female threads of the drive hub. In some embodiments,the second hub of the IO device has a non-circular cross-sectionalshape. In some embodiments, the second hub of the IO device comprisesone or more projections extending outward relative to an axis ofrotation of the IO device. In some embodiments, the second end of thedrive hub has a cross-section that is a different shape than across-section of the recess in the first end of the drive hub. In someembodiments, the first hub is configured to be inserted into the recessin the first end of the drive hub of the coupler. In some embodiments,the second hub is configured to be inserted into the recess in the firstend of the drive hub. In some embodiments, the second hub comprises aprojection with at least one detent. In some embodiments, the second hubcomprises a projection with a transverse passageway extendingtransversely across at least a portion of the projection. In someembodiments, the kits can comprise a sleeve configured to be rotatablycoupled to one or more of the first hub and the second hub of the IOdevice, the sleeve including a proximal portion configured to fit overthe shroud portion of the housing to couple the IO device to the driver.In some embodiments, the proximal portion of the sleeve comprises one ormore L-shaped slots configured to receive the one or more projections ifthe proximal portion of the sleeve is disposed over the shroud portionof the housing such that the sleeve can be rotated relative to theshroud portion to resist removal of the IO device from the driver. Insome embodiments, the proximal portion of the sleeve includes aninterior surface defining one or more detents configured to receive theone or more projections of the shroud portion. In some embodiments, thekits can further comprise a sleeve rotatably coupled to one or more ofthe first hub and the second hub of the IO device, the sleeve includinga proximal portion configured to fit over the shroud portion of thehousing if the IO device is coupled to the driver; and a resilientU-shaped clip having two legs; where the proximal portion of the sleevecomprises two elongated openings configured to align with the elongatedgrooves in the shroud portion if the proximal portion of the sleeve isdisposed on the shroud portion; and where the clip is configured toextend over the proximal portion of the sleeve with the two legsextending through the elongated openings in the sleeve and into theelongated grooves to resist removal of the sleeve and IO device from thedriver. In some embodiments, the second hub comprises a cross-sectionwith a circular central portion and a projection extending from thecentral portion in a direction away from a rotational axis of the secondhub.

Any embodiment of any of the devices, systems, and methods can consistof or consist essentially of—rather thancomprise/include/contain/have—any of the described steps, elements,and/or features. Thus, in any of the claims, the term “consisting of” or“consisting essentially of” can be substituted for any of the open-endedlinking verbs recited above, in order to change the scope of a givenclaim from what it would otherwise be using the open-ended linking verb.

The feature or features of one embodiment may be applied to otherembodiments, even though not described or illustrated, unless expresslyprohibited by this disclosure or the nature of the embodiments.

Details associated with the embodiments described above and others arepresented below.

BRIEF DESCRIPTION OF THE DRAWINGS

The following drawings illustrate by way of example and not limitation.For the sake of brevity and clarity, every feature of a given structureis not always labeled in every figure in which that structure appears.Identical reference numbers do not necessarily indicate an identicalstructure. Rather, the same reference number may be used to indicate asimilar feature or a feature with similar functionality, as maynon-identical reference numbers. The embodiments of the present drivers,coupler assemblies, intraosseous (IO) devices, and their componentsshown in the figures are drawn to scale for at least the embodimentsshown.

FIG. 1A depicts a perspective view of one embodiment of the presentintraosseous devices having a first embodiment of a cannula and a firstembodiment of a stylet.

FIG. 1B depicts a perspective view of a second embodiment of the presentcannulas.

FIGS. 1C and 1D depict a perspective views of a third embodiment of thepresent IO devices having a second embodiment of the present styletsdisposed in the cannula of FIG. 2.

FIGS. 1E and 1F depict perspective views of a fourth embodiment of thepresent IO devices having a stylets, trocars, or inner penetratorsdisposed in a cannula or outer penetrator.

FIG. 2 depicts a cross-sectional side view of one embodiment of thepresent drivers.

FIGS. 3A-3C depict various views of a first embodiment of the presentcouplers in combination with a powered driver and an IO device.

FIGS. 4A-4C depict various views of a second embodiment of the presentcouplers in combination with a powered driver and an IO device.

FIGS. 5A-5D depict various views of a third embodiment of the presentcouplers in combination with a powered driver and an IO device.

FIGS. 6A-6E depict various views of a fourth embodiment of the presentcouplers in combination with a powered driver and an IO device.

FIGS. 7A-7C depict various views of a fifth embodiment of the presentcouplers in combination with a powered driver and an IO device.

FIGS. 8A-8C depict various views of a sixth embodiment of the presentcouplers in combination with a powered driver and an IO device.

FIGS. 9A-9C depict various views of a seventh embodiment of the presentcouplers in combination with a powered driver and an IO device.

FIGS. 10A-10D depict various views of an eighth embodiment of thepresent couplers in combination with a powered driver and an IO device.

FIGS. 11A-11D depict various views of a ninth embodiment of the presentcouplers in combination with a powered driver and an IO device.

FIGS. 12A-12D depict various views of a tenth embodiment of the presentcouplers in combination with a powered driver and an IO device.

FIGS. 13A-13C depict various views of an eleventh embodiment of thepresent couplers in combination with a powered driver and an IO device.

FIGS. 14A-14B depict side cross-sectional views of a powered driver foruse with at least some embodiments of the present couplers.

FIGS. 15A-15C depict various views of embodiment of a powered driver 200m for use with at least some embodiments of the present couplers.

FIGS. 16A-16C depict various views of a twelfth embodiment of thepresent couplers in combination with a powered driver and an IO device.

FIGS. 17A-17D depict various views of a thirteenth embodiment of thepresent couplers in combination with a powered driver and an IO device.

FIGS. 18A-18C depict various views of a fourteenth embodiment of thepresent couplers in combination with a powered driver and an IO device.

FIGS. 19A-19C depict various views of a fifteenth embodiment of thepresent couplers in combination with a powered driver and an IO device.

FIGS. 20A-20B depict side cross-sectional views of a sixteenthembodiment of the present couplers in combination with a powered driverand an IO device.

FIGS. 21A-21C depict various views of a seventeenth embodiment of thepresent couplers in combination with a powered driver and an IO device.

FIGS. 22A-22B depict side cross-sectional views of an eighteenthembodiment of the present couplers in combination with a powered driverand an IO device.

FIGS. 23A-23B depict perspective and side cross-sectional views,respectively, of a nineteenth embodiment of the present couplers incombination with a powered driver and an IO device.

FIGS. 24A-24B depict perspective and side cross-sectional views,respectively, of a twentieth embodiment of the present couplers incombination with a powered driver and an IO device.

FIGS. 25A-25B depict perspective and side cross-sectional views,respectively, of a twenty-first embodiment of the present couplers incombination with a powered driver and an IO device.

FIGS. 26A-26E depict various views of a twenty-second embodiment of thepresent couplers in combination with a powered driver and an IO device.

FIGS. 27A-27C depict various views of a twenty-third embodiment of thepresent couplers in combination with a powered driver and an IO device.

FIGS. 28A-28C depict various views of a twenty-fourth embodiment of thepresent couplers in combination with a powered driver and an IO device.

FIGS. 29A-29D depict various views of a twenty-fifth embodiment of thepresent couplers in combination with a powered driver and an IO device.

FIGS. 30A-30C depict various views of a twenty-sixth embodiment of thepresent couplers in combination with a powered driver and an IO device.

FIGS. 31A-31D depict various views of a twenty-seventh embodiment of thepresent couplers in combination with a powered driver and an IO device.

FIGS. 32A-32C depict various views of a twenty-eighth embodiment of thepresent couplers in combination with a powered driver and an IO device.

FIGS. 33A-33B depict cutaway perspective and side cross-sectional views,respectively, of a twenty-ninth embodiment of the present couplers incombination with a powered driver and an IO device.

FIGS. 34A-34C depict various views of a thirtieth embodiment of thepresent couplers in combination with a powered driver and an IO device.

FIGS. 35A-35C depict various views of a thirty-first embodiment of thepresent couplers in combination with a powered driver and an IO device.

DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

The term “coupled” is defined as connected, although not necessarilydirectly, and not necessarily mechanically, two items that are “coupled”may be unitary with each other. The terms “a” and “an” are defined asone or more unless this disclosure explicitly requires otherwise. Theterm “substantially” is defined as largely but not necessarily whollywhat is specified (and includes what is specified; e.g., substantially90 degrees includes 90 degrees and substantially parallel includesparallel), as understood by a person of ordinary skill in the art. Inany disclosed embodiment, the terms “substantially,” “approximately,”and “about” may be substituted with “within [a percentage] of” what isspecified, where the percentage includes 0.1, 1, 5, and 10 percent.

The terms “comprise” (and any form of comprise, such as “comprises” and“comprising”), “have” (and any form of have, such as “has” and“having”), “include” (and any form of include, such as “includes” and“including”) and “contain” (and any form of contain, such as “contains”and “containing”) are open-ended linking verbs. As a result, a driver orcoupler assembly that “comprises,” “has,” “includes” or “contains” oneor more elements possesses those one or more elements, but is notlimited to possessing only those elements. Likewise, a method that“comprises,” “has,” “includes” or “contains” one or more steps possessesthose one or more steps, but is not limited to possessing only those oneor more steps.

Further, a device or system (or an element of a device or system) thatis configured in a certain way is configured in at least that way, butit can also be configured in other ways than those specificallydescribed.

Various types of coupler assemblies incorporating teachings of thepresent disclosure may be satisfactorily used to releasably engage oneend of a shaft extending from a driver with one end of an intraosseousdevice. For some embodiments, the powered driver may include adriveshaft having one end with a non-circular (e.g., generallyhexagonal) cross section operable to be releasably engaged with a latchmechanism disposed proximate (e.g., in) one end of a coupler assembly.For some embodiments, a coupler assembly incorporating teachings of thepresent disclosure may be referred to as a “hands free” coupler, a quickdisconnect or quick release coupler, and/or a port assembly.

A powered driver may be used to insert an IO device incorporatingteachings of the present disclosure into a selected target area ortarget site in ten seconds or less. However, various teachings of thepresent disclosure are not limited to use with powered drivers. Manualdrivers and spring powered drivers may also be used with IO devicesincorporating teachings of the present disclosure.

Examples of manual drivers are shown in co-pending patent applicationSer. No. 11/042,912 entitled Manual Intraosseous Device filed Jan. 25,2005 (published as US 2005/0165404). The term “fluid” may be used inthis application to include liquids such as, but not limited to, blood,water, saline solutions, IV solutions, plasma, or any mixture ofliquids, particulate matter, dissolved medication, and/or drugsassociated with biopsy or aspiration of bone marrow or communication offluids with bone marrow or other target sites. The term “fluid” may alsobe used in this patent application to include any body fluids and/orliquids containing particulate matter such as bone marrow and/or cellsthat may be withdrawn from a target area.

The terms “harvest” and “harvesting” may be used in this application toinclude bone and/or bone marrow biopsy and bone marrow aspiration. Boneand/or bone marrow biopsy (sometimes referred to as “needle biopsy”) maybe generally described as removing a relatively small piece or specimenof bone and/or bone marrow from a selected target area for biopsypurposes. Bone marrow aspiration (sometimes referred to as “bone marrowsampling”) may be generally described as removing larger quantities ofbone marrow from a selected target area. Relatively large quantities ofbone marrow may be used for diagnostic, transplantation, and/or researchpurposes. For example, some stem cell research techniques may requirerelatively large quantities of bone marrow.

The terms “insertion site,” “penetration site,” and “installation site”may be used in this application to describe a location on a bone atwhich an intraosseous device may be inserted or drilled into the boneand associated bone marrow. Insertion sites, penetration sites, andinstallation sites are generally covered by skin and soft tissue.

The term “intraosseous (IO) device” may be used in this application toinclude, but is not limited to, any hollow needle, hollow drill bit,penetrator assembly, bone penetrator, catheter, cannula, trocar, stylet,inner penetrator, outer penetrator, IO needle, biopsy needle, aspirationneedle, IO needle set, biopsy needle set, or aspiration needle setoperable to provide access to an intraosseous space or interior portionsof a bone. Such IO devices may be formed, at least in part, from metalalloys such as 304 stainless steel and other biocompatible materialsassociated with needles and similar medical devices.

Embodiments of the present coupler assemblies can be included in medicalprocedure trays, such as those disclosed in International PatentApplication No. PCT/US2007/078207 (published as WO 2008/033874).

Referring now to the drawings, and more particularly to FIG. 1A, showntherein and designated by the reference numeral 100 is one embodiment ofthe present intraosseous (IO) needle sets or aspiration needle sets.Aspiration needle set 100 a comprises a hollow outer penetrator orcannula 110 a, a corresponding inner penetrator or stylet (or trocar)120, and a hub assembly 130 a. In the embodiment shown, first end 111 aof cannula 110 a and first end 121 of stylet 120 are operable orconfigured to penetrate a bone and associated bone marrow. Variousfeatures of first end 111 a of cannula 110 a and first end 121 of stylet120 are shown in more detail in FIGS. 1B-ID. First end 101 of IO needleset 100 corresponds generally with first end 111 a of cannula 110 a andfirst end 121 of stylet 120.

In the embodiment shown, cannula 110 a includes a plurality of markings104 disposed on exterior portions of the cannula. Markings 104 may bereferred to as “positioning marks” or “depth indicators,” and may beused to indicate the depth of penetration of needle set 100 into a boneand associated bone marrow. In some embodiments, cannula 110 a may havea length of approximately sixty (60) millimeters and/or a nominaloutside diameter of approximately 0.017 inches (e.g., correspondinggenerally to the dimensions of a sixteen (16) gauge needle). Cannula 110a and/or stylet 120 may be formed from stainless steel or other suitablebiocompatible materials. In some embodiments, markings 104 are spaced atone (1) centimeter intervals on exterior portions of cannula 110 a. Insome embodiments, one or more side ports 106 may be formed in exteriorportions of cannula 110 a spaced from first end 111 a.

Hub assembly 130 a may be configured and/or used to releasably disposestylet 120 within the longitudinal bore or lumen of cannula 110 a. Inthe embodiment shown, hub assembly 130 a includes a first hub 140 a anda second hub 150 a. A second end of cannula 110 a, opposite from firstend 111 a, may be securely engaged with hub 140 a. The second end ofstylet 120, opposite from first end 121, may be securely engaged withthe first end of hub 150 a. As shown in FIG. 1A, cannula 110 a mayextend longitudinally from first end 141 of hub 140 a. Stylet 120 mayalso extend from the first end of hub 150 a. The second end of hub 140 amay include a standard Luer lock fitting which may be releasably engagedwith a corresponding Luer lock fitting disposed within the first end ofsecond hub 150 a. The Luer lock fitting disposed on the second end ofhub 140 a may be in fluid communication with the bore or passage incannula 110 a, and may be operable to be releasably engaged with astandard syringe type fitting and/or a standard intravenous (IV)connection. In the embodiment shown, hub 150 a includes second end 152that generally corresponds with second end 132 of hub assembly 130 a andsecond end 102 of IO needle set 100. Hub 140 a may include first end 141which may generally correspond with first end 131 of hub assembly 130 a.Cannula 110 a may extend longitudinally from first end 141 of hub 140 aand first end 131 of hub assembly 130.

In the embodiment shown, the second end of a hub assembly may beoperable to be disposed within a receptacle formed in a couplerassembly, as described in more detail below. One feature of the presentdisclosure may include forming a hub assembly which may be releasablyengaged within a first receptacle disposed in a first end of a couplerassembly (e.g., receptacle 263 proximate first end 261 of elongated core260 as shown in FIGS. 6A-6B of International Patent Application No.PCT/US2007/078207 (published as WO 2008/033874)). The dimensions andconfiguration of receptacle 263 may be selected to prevent rotation ofhub 150 a relative to hub 140 a if hub assembly 130 a is disposed inreceptacle 263 (e.g., while inserting (rotating) an IO device into abone and associated bone marrow). A powered driver may be releasablyengaged with a second receptacle disposed in a second end of the couplerassembly (e.g., receptacle 264 proximate second end 262 of elongatedcore 260 as shown in FIGS. 6A-6B of International Patent Application No.PCT/US2007/078207 (published as WO 2008/033874)).

In the embodiment shown, intraosseous device or aspiration needle set100 a includes first end 151 of hub 150 a spaced from second end 142 ofhub 140 a. Portions of stylet 120 extending from first end 151 of hub150 a are shown slidably disposed within lumen or longitudinal bore 118of cannula 110 a. Hub assembly 130 a may include first end 131 which maycorrespond generally with first end 141 of hub 140 a. Hub assembly 130 amay also include second end 132 which may correspond generally withsecond end 152 of hub 150 a and second end 102 of hub assembly 130 a, asshown. Cannula 110 a may be attached to and extend from first end 141 ofhub 140 a. Second end 142 of hub 140 a may include one-half a typicalLuer lock connection or fitting operable to be releasably engaged withcorresponding portions of a Luer lock connection or fitting disposed infirst end 151 of second hub 150 a. For embodiments such as the one shownin FIG. 1A, first end 131 of hub assembly 130 a may correspond withfirst end 141 of first hub 140 a. Second end 152 of second hub 150 a maycorrespond with second end 132 of hub assembly 130 a and second end 102of aspiration needle set 100 a.

At least one portion of hub assembly 130 a may have a generallyhexagonal cross section operable to be received within the generallyhexagonal cross section of receptacle 263 disposed proximate first end251 of coupler assembly 250, as shown in FIGS. 6A-6B of InternationalPatent Application No. PCT/US2007/078207 (published as WO 2008/033874).For some embodiments, portions of first hub 140 a disposed adjacent toreduced outside diameter portion 143 may have generally hexagonal crosssections, as shown in FIG. 1A. In other embodiments, various crosssections other than hexagonal may be satisfactorily used to releasablyengage a powered driver with one end of a coupler assembly and anintraosseous device with an opposite end of the coupler assembly.Aspiration needle sets may include a trocar, stylet or penetrator incombination with an associated cannula, catheter or outer penetrator.However, biopsy needles formed in accordance with teachings of thepresent disclosure may or may not include a trocar, stylet or innerpenetrator.

Hub 140 a may include second end 142 with opening 144 formed therein. Apassageway may extend from second end 142 towards first end 141 of hub140 a, as illustrated in FIGS. 6A-6B of International Patent ApplicationNo. PCT/US2007/078207 (published as WO 2008/033874). A passageway may beoperable to communicate fluids with lumen 118 of cannula 100 a. Secondend 142 of hub 140 may include various features of a conventional Luerlock connection or fitting, including threads 148, and correspondingthreads 158 may be formed within first end 151 of hub 150 a, as shown inFIGS. 6A-6B of International Patent Application No. PCT/US2007/078207(published as WO 2008/033874).

For some applications hub 140 a and hub 150 a may, for example, beformed using injection molding techniques. For such embodiments hub 140a may include reduced outside diameter portion 143 disposed betweenfirst end 141 and second end 142. In a similar manner a plurality ofvoid spaces or cutouts 153 may be formed in hub 150 a adjacent to andextending from second end 152 in the direction of first end 151. Theconfiguration and dimensions of reduced diameter portion 143 and/orcutouts 153 may be varied to optimize associated injection moldingtechniques and at the same time provide required configurations,dimensions and material strength to allow associated hub assembly 130 ato function as described in this disclosure.

In some embodiments, tip 123 of stylet 120 may be disposed relativelyclose to a tip of cannula 110 a. For some applications, first end 121 oftrocar 120 and first end 111 a of cannula 110 a may be ground at thesame time to form adjacent cutting surfaces. Grinding ends 111 a and 121at the same time may result in forming a single cutting unit to formgenerally matching cutting edges. Other types of cutting surfaces formedin accordance with teachings of the present disclosure may be discussedlater (e.g., as described with reference to FIGS. 1B-ID).

FIGS. 1B-ID show a second example of cutting surfaces and tips which maybe formed adjacent to the ends of a cannula and/or an associated trocarin the present embodiments. In the embodiment shown, outer penetrator orcannula 110 b may include first end 111 b having a plurality of cuttingsurfaces 114 b formed adjacent to opening 116 in first end 111. Opening116 may communicate with and form a portion of an associatedlongitudinal bore or lumen 118. For some applications cutting surfaces114 b may be formed using electrical discharge machining (EDM)techniques or otherwise, as described in WO 2008/033874. In theembodiment shown, first end 111 b has a generally tapered configurationor reduced outside diameter as compared with other portions of cannula110 b In other embodiments, first end 111 b has an outside diameter thatis equal to the outside diameter of other portions of cannula 110 b(e.g., cannula 110 b can have a constant outside diameter along theentire length of the cannula). Cutting surfaces 114 b may, for example,be formed using machine grinding techniques. In some embodiments, suchas the one shown, end 111 b of cannula 110 b may include six groundcutting surfaces 114 b with respective crowns 115 therebetween. Forminga biopsy needle set and/or biopsy needle with tapered end 111 b and aplurality of cutting surfaces 114 b and crowns 115 may provide improveddrilling performance (e.g., relative to others configurations) when theresulting biopsy needle set and/or biopsy needle is used with a powereddriver in accordance with teachings of the present disclosure. For someapplications, a helical groove 117 may be formed within longitudinalbore 118 proximate opening 116. Helical groove 117 may assist withretaining a biopsy specimen or a bone marrow specimen withinlongitudinal bore 118. For example, a single thread may be disposedwithin the longitudinal bore or lumen of the cannula such that thehelical groove 117 is defined between turns of the thread. Varioustechniques and procedures may be satisfactorily used to place the singlethread or otherwise form the helical groove, as described WO2008/033874.

As shown in FIG. 1C, a biopsy needle set 100 b may include cannula orouter penetrator 110 b with stylet or inner penetrator 120 b slidablydisposed therein. The proximal ends of cannula 110 b and stylet 120 bmay be similar to those of cannula 110 a and stylet 120 depicted in FIG.1A (e.g., may include hubs 140 a and 150 a, respectively). For someapplications first end 101 of biopsy needle set 100 b may minimizedamage to skin and soft body tissue at an insertion site. For someapplications inner penetrator or trocar 120 b may include first end 121having a plurality of cutting surfaces 125 and 126 formed on exteriorportions thereof extending from associated tip 123 towards second end oftrocar or inner penetrator 120 b. For some applications one or morecutting surfaces 125 may be formed having length 127 extending from tip123 to associated cutting surfaces 114 b in associated cannula 110 b.One or more cutting surfaces 126 may be formed adjacent to each cuttingsurface 125 with second length 128. First length 127 may be greater thansecond length 128. As shown, lengths 127 and 128 are measured parallelto the central longitudinal axis of stylet 120 b. The ratio of firstlength 127 and second length 128 may be varied in accordance withteachings of the present disclosure to provide optimum performance forpenetrating a selected bone and associated bone marrow. Additionaldetails of some embodiments of first end 101 are described in WO2008/033874.

FIGS. 1E and 1F depict perspective views of a fourth embodiment of thepresent IO devices having a stylets, trocars, or inner penetratorsdisposed in a cannula or outer penetrator. In the embodiment shown,device 100 a is configured to provide access to a patient's circulatorysystem via the patient's bone (e.g., as opposed to extracting abone-marrow sample). In the embodiment shown, device or penetratorassembly 100 c may include first hub 140 c, connector or second hub 150c, outer penetrator 110 c, and inner penetrator 120 c. Penetratorassembly 100 c may include an outer penetrator such as a cannula, hollowtube or hollow drill bit and an inner penetrator such as a stylet ortrocar. Various types of stylets and/or trocars may be disposed withinan outer penetrator. For some applications outer penetrator or cannula110 c may be described as a generally elongated tube sized to receiveinner penetrator or stylet 120 c therein. Portions of inner penetrator120 c may be disposed within longitudinal passageway 118 extendingthrough outer penetrator 110 c. The outside diameter of inner penetrator120 c and the inside diameter of longitudinal passageway 118 may beselected such that inner penetrator 120 c may be slidably disposedwithin outer penetrator 110 c.

Metallic disc 170 may be disposed within opening 186 for use inreleasably attaching connector 150 c with a magnet disposed on adriveshaft (e.g., driveshaft 222 of driver 200 shown in FIG. 2), suchas, for example, on end of the driveshaft (e.g., end 224 of driveshaft222). End 122 of inner penetrator 120 c may be spaced from metallic disc170 with insulating or electrically nonconductive material disposedtherebetween. In other embodiments, disc 170 can be magnetic ormagnetized to be attracted to a driveshaft (e.g., 222) that ismetallic). Tip 111 c of outer penetrator 110 c and/or tip 121 of innerpenetrator 120 c may be operable to penetrate bone and associated bonemarrow. The configuration of tips 111 c and/or 121 may be selected topenetrate a bone or other body cavities with minimal trauma. First endor tip 121 of inner penetrator 120 c may be trapezoid shaped and mayinclude one or more cutting surfaces. In one embodiment outer penetrator110 c and inner penetrator 120 c may be ground together as one unitduring an associated manufacturing process. Providing a matching fitallows respective tips 111 c and 121 to act as a single drilling unitwhich facilitates insertion and minimizes damage as portions ofpenetrator assembly 100 c are inserted into a bone and associated bonemarrow. Outer penetrator 110 c and/or inner penetrator 120 c may beformed from stainless steel, titanium or other materials of suitablestrength and durability to penetrate bone.

Hub 140 c may be used to stabilize penetrator assembly 100 c duringinsertion of an associated penetrator into a patient's skin, soft tissueand adjacent bone at a selected insertion site. Second end 142 of hub140 c may be operable for releasable engagement or attachment withassociated connector 150 c. First end 141 of hub 140 c may have a sizeand configuration compatible with an associated insertion site for outerpenetrator 110 c. Connector 150 c and attached inner penetrator 120 cmay be releasably engaged with each other by Luer type fittings,threaded connections or other suitable fittings formed on second end 142of hub 140 c. Outer penetrator 110 c extends from first end 141 of hub140 c. For some applications connector 150 c may be described as agenerally cylindrical tube defined in part by second end 152 and firstend 151. The exterior of connector 150 c may include an enlarged taperedportion adjacent to end 181. A plurality of longitudinal ridges 190 maybe formed on the exterior of connector 150 c to allow an operator tograsp associated penetrator assembly 100 c during attachment with adriveshaft. Longitudinal ridges 190 also allow connector 150 c to begrasped for disengagement from hub 140 c when outer penetrator 110 c hasbeen inserted into a bone and associated bone marrow.

First end 151 of connector 150 c may include opening 185 sized toreceive second end 142 of hub 140 c therein. Threads 158 may be formedin an opening adjacent to first end 151 of connector 150 c, as shown.Threaded fitting 158 may be used in releasably attaching connector 150 cwith threaded fitting 148 adjacent to second end 142 of hub 140 c.Second end 142 of hub 140 c may include a threaded connector 148 orother suitable fittings formed on the exterior thereof. Second end 142may have a generally cylindrical pin type configuration compatible withreleasably engaging second end or box end 182 of connector 150 c. Forsome applications end 141 of hub 140 c may have the generalconfiguration of a flange. Angular slot or groove 188 sized to receiveone end of protective cover or needle cap 234 may be formed in end 202.Slot or groove 204 may be used to releasable engage a needle cover (notexpressly shown) with penetrator assembly 100 c.

For some applications a penetrator assembly may include only a single,hollow penetrator. For other applications a penetrator assembly mayinclude an outer penetrator such as a cannula, hollow needle or hollowdrill bit and an inner penetrator such as a stylet, trocar or otherremovable device disposed within the outer penetrator. Penetrator 110 cis one example of a single, hollow penetrator or cannula. The size of apenetrator may vary depending upon the intended application for theassociated penetrator assembly. Penetrators may be relatively small forpediatric patients, medium size for adults and large for oversizeadults. By way of example, a penetrator may range in length from five(5) mm to thirty (30) mm. The diameter of a penetrator may range fromeighteen (18) gauge to ten (10) gauge. The length and diameter of thepenetrator used in a particular application may depend on the size of abone to which the apparatus may be applied. Penetrators may be providedin a wide variety of configurations depending upon intended clinicalpurposes for insertion of the associated penetrator. For example, theremay be one configuration for administering drugs and/or fluids to apatient's bone marrow and an alternative configuration for sampling bonemarrow and/or blood from a patient.

For some applications connector 150 c may be described as having agenerally cylindrical configuration defined in part by second end 152and first end 151. Exterior portions of connector 150 c may include anenlarged tapered portion adjacent to end 181. A plurality oflongitudinal ridges 190 may be formed on the exterior of connector 150 cto allow an operator to grasp associated penetrator assembly 100 cduring attachment with a driveshaft. Longitudinal ridges 190 also allowconnector 150 c to be grasped for disengagement from hub 140 c whenouter penetrator 110 c has been inserted into a bone and associated bonemarrow. Second end 152 of connector of 150 c may included opening 186sized to receive portions driveshaft 52 therein. A plurality of webs 136may extend radially outward from connector receptacle 186. Webs 136cooperate with each other to form a plurality of openings 138 adjacentto second end 152. Opening 186 and openings 138 cooperate with eachother to form portions of a connector receptacle operable to receiverespective portions of a connector (not expressly shown) therein.

FIG. 2 depicts a cross-sectional view of one embodiment of a driver thatcan be used with embodiments of the present drivers, coupler assemblies,and kits. In the embodiment shown, powered driver 200 may be used toinsert one of the present intraosseous devices into a bone andassociated bone marrow. Powered driver 200 may include housing 210having a general configuration similar to a small pistol defined in partby handle 214. Various components associated with powered driver 200 maybe disposed within housing 210 (e.g., handle 214). For example a powersource such as battery pack 216 may be disposed within handle 214.Housing 210 may be formed from relatively strong, heavy duty polymericmaterials such as polycarbonate or other satisfactory materials. Forsome applications housing 210 may be formed in two halves (not expresslyshown) which may be joined together with a fluid tight seal to protectvarious components of powered driver 200 disposed therein.

Motor 218 and gear assembly 220 may be disposed within portions ofhousing 210 adjacent to handle 214. Motor 218 and gear assembly 220 maybe generally aligned with each other. Motor 218 may be rotatably engagedwith one end of gear assembly 220. Driveshaft 222 may be rotatablyengaged with and extend from another end of gear assembly 220 oppositefrom motor 218. For some applications both motor 218 and gear assembly220 may have generally cylindrical configurations. Distal end or firstend 211 of housing 210 may include an opening with portions ofdriveshaft 222 extending through the opening, as shown. For someapplications, end 224 or the portion of driveshaft 222 extending fromfirst end 211 of housing 210 may have a generally hexagonal crosssection with surfaces 226 disposed thereon. Receptacle 263 disposed insecond end 252 of coupler assembly 250 may have a matching generallyhexagonal cross section, as shown in FIGS. 6A-6C of International PatentApplication No. PCT/US2007/078207 (published as WO 2008/033874).

Surfaces 226 may extend generally parallel with each other and parallelwith respect to a longitudinal axis or rotational axis of driveshaft222. One or more tapered surfaces 228 may also be formed on end 224 toassist with releasably engaging powered driver 200 with coupler assembly250. Embodiments of powered driver 200 include speed reduction ratios,for example, of between 60:1 and 80:1, resulting in driveshaft RPMs thatare reduced relative to motor RPMs. Coupler assemblies havingcorresponding openings or receptacles may be releasably engaged with end224 extending from first end 211 of powered driver 200. For example, end224 extending from first end 211 of housing 210 may be releasablyengaged with receptacle 264 disposed proximate second end 252 of couplerassembly 250, as shown in FIGS. 6A-6B.

For some applications thrust bearing 241 may be disposed between firstend or distal end 211 of housing 210 and adjacent portions of gearassembly 220. Thrust bearing 242 may be disposed between second end orproximal end 212 of housing 210 and adjacent portions of motor 218.Thrust bearings 241 and 242 may limit longitudinal movement of motor218, gear assembly 220 and driveshaft 222 within associated portions ofhousing 210. Trigger assembly 244 may also be disposed within housing210 proximate handle 214. Trigger assembly 244 may include trigger orcontact switch 246. Motor 218 may be energized and deenergized byalternately depressing and releasing trigger 246. Electrical circuitboard 247 may also be disposed within housing 210. Electrical circuitboard 247 may be electrically coupled with trigger assembly 244, motor218, power supply 216 and indicator light 248. For some applicationsindicator light 248 may be a light emitting diode (LED) or a small moreconventional light bulb. For some applications indicator light 248 maybe activated when ninety percent (90%) of electrical storage capacity ofbattery pack 216 has been used. The configuration and dimensions of anintraosseous device formed in accordance with teachings of the presentdisclosure may vary depending upon respective intended applications foreach intraosseous device. For example the length of a biopsy needleformed in accordance with teachings of the present disclosure may varyfrom approximately five (5) millimeters to thirty (30) millimeters.

Couplers and coupler assemblies incorporating teachings of the presentdisclosure may function as “quick release mechanisms” operable to engageand disengage an IO device from a powered driver (e.g., a driverdisposed within a flexible containment bag or sterile sleeve). Inapplications involving a flexible containment bag or sterile sleeve,such coupler assemblies may allow rotation of an IO device (e.g., biopsyneedle or needle set) without damage to the flexible containment bag orsterile sleeve, and one end of the coupler assembly may be operable toform a fluid seal or fluid barrier with adjacent portions of thecontainment bag or sterile sleeve. A coupler assembly incorporatingteachings of the present disclosure may also be described as a portassembly attached to a containment bag. Such port assemblies may alloweasy engagement or disengagement of a powered driver from an IO deviceand at the same time allow the powered driver to “power in and powerout” an IO device from an insertion site. FIGS. 3A-35C depict variousembodiments of the present couplers in conjunction with drivers and/orIO devices; because the drivers and/or IO devices are similar in manyrespects to driver 200 of FIG. 2 and IO devices 100 a-100 c of FIGS.1A-IF, the differences in the drivers and/or IO devices are primarilydescribed below.

FIGS. 3A-3C depict various views of a first embodiment 300 a of thepresent couplers in combination with a powered driver 200 a and an IOdevice 100 d that is configured to provide access to an interior of abone (e.g., similar in some respects to IO device 100 c). In theembodiment shown, coupler 300 a comprises a drive hub 304 a having afirst end 308 a and a second end 312 a configured to be coupled in fixedrelation to a driveshaft 222 a (of a driver 200 a having a housing 210a) such that at least a portion of the drive hub is disposed outside thehousing of the driver. In the embodiment shown, first end 308 a of drivehub 304 a includes female threads 316 a configured to be coupled to anintraosseous (IO) device 100 d, as shown. More particularly, in theembodiment shown, hub assembly 130 d (and more specifically second hub150 d, in the depicted embodiment) of IO device 100 d includes malethreads 320 a corresponding to female threads 316 a. In the embodimentshown, threads 316 a (and 320 a) are configured to tighten if the driverrotates drive hub 304 a and IO device 100 d (coupled to the drive hub)in a clockwise direction. In the embodiment shown, drive hub 304 a isunitary with driveshaft 222 a (drive hub 304 a and driveshaft 222 acomprise a single piece of material). In other embodiments, drive hub304 a may be coupled to driveshaft 222 a in any manner (e.g., welding,threads, press-fit, and/or the like) that permits the function describedin this disclosure.

FIGS. 4A-4C depict various views of a second embodiment 300 b of thepresent couplers in combination with a powered driver 200 b and an IOdevice 100 e that is configured for obtaining a sample of bone and/orbone marrow (e.g., similar in some respects to IO devices 100 a and/or100 b). Coupler 300 b is similar in some respects to coupler 300 a. Inthe embodiment shown, coupler 300 b comprises a drive hub 304 b having afirst end 308 b and a second end 312 b configured to be coupled in fixedrelation to a driveshaft 222 b (of a driver 200 b having a housing 210b) such that at least a portion of the drive hub is disposed outside thehousing of the driver. In the embodiment shown, first end 308 b of drivehub 304 b includes female threads 316 b configured to be coupled to anintraosseous (IO) device 100 e, as shown. More particularly, in theembodiment shown, hub assembly 130 e (and more specifically first hub140 e, in the depicted embodiment) of IO device 100 e includes malethreads 320 b corresponding to female threads 316 b. Coupler 300 bdiffers from coupler 300 a, for example, in that drive hub 304 bincludes a recess 324 b that is sized to receive a second hub (notshown, but similar to second hub 150 a of IO device 100 a). In theembodiment shown, threads 316 b (and 320 b) are configured to tighten ifthe driver rotates drive hub 304 b and IO device 100 e (coupled to thedrive hub) in a clockwise direction. Coupler 300 b further differs fromcoupler 300 a, for example, in that second end 312 b of drive hub 304 bincludes female threads 328 a configured to be coupled to driveshaft 222b of driver 200 b. In the embodiment shown, driveshaft 222 b has adistal end 224 b and includes male threads 332 b adjacent correspondingto female threads 328 b. In the embodiment shown, second end 312 b ofdrive hub 304 b comprises a flange 334 b extending outwardly relative toan axis of rotation of the drive hub, as shown. Flange 334 b may, forexample, be used to connect coupler 300 b to a containment bag or thelike (e.g., as disclosed WO 2008/033874).

FIGS. 5A-5D depict various views of a third embodiment 300 c of thepresent couplers in combination with a powered driver 200 c and an IOdevice 100 f that is configured to provide access to an interior of abone (e.g., similar in some respects to IO device 100 c). In theembodiment shown, coupler 300 c comprises a drive hub 304 c having afirst end 308 c and a second end 312 c including a recess 336 cconfigured to receive driveshaft 222 c of driver 200 c. In thisembodiment, second end 312 c is configured such that if driveshaft 222 cis inserted into recess 336 c, an interference fit between drive hub 304c and driveshaft 222 c will resist rotation of the drive hub relative tothe driveshaft (and/or resist removal of drive hub 304 c from driveshaft222 c). For example, in the embodiment shown, driveshaft 222 c issubstantially rigid (e.g., comprises a metal such as stainless steel)and has a transverse dimension that is larger than a correspondingtransverse dimension of recess 336 c such that as driveshaft 222 c isinserted into recess 336 c, drive hub 304 c will deflect slightly andimpart a compressive force on driveshaft 222 c. Drive hub 304 c cancomprise, for example, a resilient material such as a resilient polymer,or any other material permitting the described function. In someembodiments, the driveshaft and the recess have dissimilarcross-sectional shapes. For example, in the embodiment shown (FIG. 5D),driveshaft 222 c has a hexagonal cross-sectional shape and recess 336 chas a circular cross-sectional shape. In other embodiments, thedriveshaft and recess can have similar cross-sectional shapes (e.g.,driveshaft 222 c can have a circular cross-sectional shape. Tofacilitate insertion of driveshaft 222 c into recess 336 c, one or bothof driveshaft 222 c and recess 336 c can be tapered (e.g., driveshaft222 c can have a transverse dimension that is relatively smaller atdistal end 224 c and increases along a portion of driveshaft 222 capproaching housing 210 c, and/or recess 336 c can have a relativelylarger transverse dimension (e.g., diameter) at second end 312 c thatincreases along a portion of recess 336 c approaching first end 308 c).In the embodiment shown, first end 308 c is configured to be coupled toIO device 100 f (e.g., to resist rotation of the IO device relative tothe drive hub). For example, in the embodiment shown, drive hub 304 c isunitary with a portion of hub assembly 130 f (and more specificallyunitary with second hub 150 f, in the depicted embodiment).

FIGS. 6A-6E depict various views of a fourth embodiment 300 d of thepresent couplers in combination with a powered driver 200 d and an IOdevice 100 g that is configured for obtaining a sample of bone and/orbone marrow (e.g., similar in some respects to IO devices 100 a and/or100 b). In the embodiment shown, coupler 300 d comprises a drive hub 304d having a first end 308 d and a second end 312 d including a recess 336d configured to receive driveshaft 222 d of driver 200 d. In thisembodiment, second end 312 d is configured such that if driveshaft 222 dis inserted into recess 336 d, an interference fit between drive hub 304d and driveshaft 222 d will resist rotation of the drive hub relative tothe driveshaft (and/or resist removal of the drive hub from driveshaft).For example, in the embodiment shown, driveshaft 222 d is substantiallyrigid (e.g., comprises a metal such as stainless steel) and has atransverse dimension that is larger than a corresponding transversedimension of recess 336 d such that as driveshaft 222 d is inserted intorecess 336 d, drive hub 304 d will deflect slightly and impart acompressive force on driveshaft 222 d. Drive hub 304 d can comprise, forexample, a resilient material such as a resilient polymer, or any othermaterial permitting the described function. In some embodiments, thedriveshaft and the recess have dissimilar cross-sectional shapes. Forexample, in the embodiment shown (FIG. 6E), driveshaft 222 d has ahexagonal cross-sectional shape and recess 336 d has a circularcross-sectional shape. In other embodiments, the driveshaft and recesscan have similar cross-sectional shapes (e.g., driveshaft 222 d can havea circular cross-sectional shape). To facilitate insertion of driveshaft222 d into recess 336 d, one or both of driveshaft 222 d and recess 336d can be tapered (e.g., driveshaft 222 d can have a transverse dimensionthat is relatively smaller at distal end 224 d and increases along aportion of driveshaft 222 d approaching housing 210 d, and/or recess 336d can have a relatively larger transverse dimension (e.g., diameter) atsecond end 312 d that increases along a portion of recess 336 dapproaching first end 308 d). Further, in this embodiment driveshaft 222d comprises an enlarged cap member 223 d that can comprise a resilientmaterial (e.g., a resilient polymer) to further facilitate insertion ofdriveshaft 222 d into recess 336 d.

Coupler 300 d further differs from coupler 300 c, for example, in thatfirst end 308 d includes a second recess 340 d that is sized to receivea hub (e.g., first hub 140 g) of IO device 100 g, and first end 308 d isconfigured such that if hub 140 g is inserted into recess 340 d, aninterference fit between drive hub 308 d and hub 140 g will resistrotation of IO device 100 g relative to drive hub 304 d. As describedabove for drive hub 304 d and driveshaft 222, drive hub 304 d cancomprise, for example, a resilient material such as a resilient polymer,or any other material permitting the described function. In someembodiments, hub 140 g and recess 340 d have dissimilar cross-sectionalshapes. For example, in the embodiment shown (FIG. 6D), hub 140 g has ahexagonal cross-sectional shape and recess 340 d has a circularcross-sectional shape. In other embodiments, the driveshaft and recesscan have similar cross-sectional shapes (e.g., hub 140 g can have acircular cross-sectional shape). To facilitate insertion of hub 140 ginto recess 340 d, one or both of hub 140 g and recess 340 d can betapered (e.g., hub 140 g can have a transverse dimension that isrelatively smaller at second end 142 and increases along a portion ofhub 140 g approaching first end 141, and/or recess 340 d can have arelatively larger transverse dimension (e.g., diameter) at first end 308d that increases along a portion of recess 340 d approaching second end312 d). Coupler 300 d further differs from coupler 300 c, for example,in that drive hub 304 d includes a recess 324 d that is sized to receivea second hub (not shown, but similar to second hub 150 a of IO device100 a) in combination with first hub 140 g of IO device 100 g.

FIGS. 7A-7C depict various views of a fifth embodiment 300 e of thepresent couplers in combination with a powered driver 200 e and an IOdevice 100 h that is configured to provide access to an interior of abone (e.g., similar in some respects to IO device 100 c). In theembodiment shown, coupler 300 e comprises a drive hub 304 e having afirst end 308 e and a second end 312 e including a recess 336 econfigured to receive driveshaft 222 e of driver 200 e. In thisembodiment, second end 312 e is configured such that if driveshaft 222 eis inserted into recess 336 e, an interference fit between drive hub 304e and driveshaft 222 e will resist rotation of the drive hub relative tothe driveshaft (and/or resist removal of drive hub 304 e from driveshaft222 e). For example, in the embodiment shown, driveshaft 222 e issubstantially rigid (e.g., comprises a metal such as stainless steel),and drive hub 304 e includes a plurality of tabs or ribs 344 e (e.g.,with a triangular cross-sectional shape, as shown) extending into recess336 e. In this embodiment, tabs 344 e are configured to deform if thedriveshaft is inserted into the recess. In the embodiment shown, recess336 e has at least one transverse dimension that is larger than atransverse dimension of driveshaft 222 e, however, tabs 344 e extendinward and a transverse distance between opposing tabs 344 e is lessthan a transverse dimension of driveshaft 222 e, such that tabs 344 ewill deflect and/or compress and impart a compressive force ondriveshaft 222 e. Drive hub 304 e can comprise, for example, a resilientmaterial such as a resilient polymer, or any other material permittingthe described function. In the embodiment shown, first end 308 e isconfigured to be coupled to IO device 100 h (e.g., to resist rotation ofthe IO device relative to the drive hub). For example, in the embodimentshown, drive hub 304 e is unitary with a portion of hub assembly 130 h(e.g., unitary with second hub 150 h). While not shown in FIGS. 7A-7C,other embodiments can comprise a second recess in first end 308 e withtabs extending into the recess to form an interference fit with a hub ofan IO device (e.g., similar to coupler 100 d).

FIGS. 8A-8C depict various views of a sixth embodiment 300 f of thepresent couplers in combination with a powered driver 200 f and an IOdevice 100 i that is configured to provide access to an interior of abone (e.g., similar in some respects to IO device 100 c). In theembodiment shown, coupler 300 f comprises a drive hub 304 f having afirst end 308 f and a second end 312 f including a recess 336 fconfigured to receive driveshaft 222 f of driver 200 f. In thisembodiment, second end 312 f is configured such that if driveshaft 222 fis inserted into recess 336 f, an interference fit between drive hub 304f and driveshaft 222 f will resist rotation of the drive hub relative tothe driveshaft (and/or resist removal of drive hub 304 f from driveshaft222 f). For example, in the embodiment shown, driveshaft 222 f comprisesone or more barbs 348 f (e.g., an annular barb surrounding the perimeterof the driveshaft, or one or more discrete barbs disposed around thedriveshaft) with a transverse dimension between outermost portions ofbarb(s) 348 f that is larger than a corresponding transverse dimensionof recess 336 f such that as driveshaft 222 f is inserted into recess336 f, drive hub 304 f will deflect slightly and impart a compressiveforce on barb(s) 348 f. In the embodiment shown, driveshaft 222 f issubstantially rigid (e.g., comprises a metal such as stainless steel).Drive hub 304 f can comprise, for example, a resilient material such asa resilient polymer, or any other material permitting the describedfunction. In some embodiments, the driveshaft and the recess havesimilar cross-sectional shapes. For example, in the embodiment shown(FIG. 5D), driveshaft 222 f has an annular barb 348 f with a circularcross-sectional shape and recess 336 f has a circular cross-sectionalshape. In other embodiments, the driveshaft and recess can havedissimilar cross-sectional shapes (e.g., driveshaft 222 f can have aplurality of discrete barbs) and recess 336 f can have a circularcross-sectional shape. To facilitate insertion of driveshaft 222 f intorecess 336 f, one or both of driveshaft 222 f and recess 336 f can betapered (e.g., driveshaft 222 f can have a transverse dimension that isrelatively smaller at distal end 224 f and increases along a portion ofdriveshaft 222 f approaching housing 210 f, as shown, and/or recess 336f can have a relatively larger transverse dimension (e.g., diameter) atsecond end 312 f that increases along a portion of recess 336 fapproaching first end 308 f). In the embodiment shown, first end 308 fis configured to be coupled to IO device 100 i (e.g., to resist rotationof the IO device relative to the drive hub). For example, in theembodiment shown, drive hub 304 f is unitary with a portion of hubassembly 130 i (e.g., unitary with second hub 150 i).

FIGS. 9A-9C depict various views of a seventh embodiment 300 g of thepresent couplers in combination with a powered driver 200 g and an IOdevice 100 j that is configured for obtaining a sample of bone and/orbone marrow (e.g., similar in some respects to IO devices 100 a and/or100 b). In the embodiment shown, coupler 300 g comprises a drive hub 304f having a first end 308 f and a second end 312 f including a recess 336f configured to receive driveshaft 222 g of driver 200 g. In thisembodiment, second end 312 g is configured such that if driveshaft 222 gis inserted into recess 336 g, an interference fit between drive hub 304g and driveshaft 222 g will resist rotation of the drive hub relative tothe driveshaft (and/or resist removal of the drive hub from driveshaft).For example, in the embodiment shown, driveshaft 222 g comprises one ormore barbs 348 g (e.g., an annular barb surrounding the perimeter of thedriveshaft, or one or more discrete barbs disposed around thedriveshaft) with a transverse dimension between outermost portions ofbarb(s) 348 g that is larger than a corresponding transverse dimensionof recess 336 g such that as driveshaft 222 g is inserted into recess336 g, drive hub 304 g will deflect slightly and impart a compressiveforce on barb(s) 348 g. In the embodiment shown, driveshaft 222 g issubstantially rigid (e.g., comprises a metal such as stainless steel).Drive hub 304 g can comprise, for example, a resilient material such asa resilient polymer, or any other material permitting the describedfunction. In some embodiments, the driveshaft and the recess havesimilar cross-sectional shapes. For example, in the embodiment shown(FIG. 5D), driveshaft 222 g has an annular barb 348 g with a circularcross-sectional shape and recess 336 g has a circular cross-sectionalshape. In other embodiments, the driveshaft and recess can havedissimilar cross-sectional shapes (e.g., driveshaft 222 g can have aplurality of discrete barbs) and recess 336 g can have a circularcross-sectional shape. To facilitate insertion of driveshaft 222 g intorecess 336 g, one or both of driveshaft 222 g and recess 336 g can betapered (e.g., driveshaft 222 g can have a transverse dimension that isrelatively smaller at distal end 224 g and increases along a portion ofdriveshaft 222 g approaching housing 210 g, as shown, and/or recess 336g can have a relatively larger transverse dimension (e.g., diameter) atsecond end 312 g that increases along a portion of recess 336 gapproaching first end 308 g).

Drive hub 304 g differs from drive hub 304 f, for example, in thatrecess 336 g is defined by a cylindrical wall 352 g that is, in turn, atleast partially (e.g., up to entirely, as shown) surrounded by a second(e.g., annular) recess 356 g that permits wall 352 g to flex tofacilitate insertion of driveshaft. Drive hub 304 g further differs fromdrive hub 304 f, for example, in that first end 308 g includes a secondrecess 340 g that is sized to receive a hub (e.g., first hub 140 j) ofIO device 100 g, and first end 308 g is configured such that if hub 140j is inserted into recess 340 g, an interference fit between drive hub308 g and hub 140 j will resist rotation of IO device 100 j relative todrive hub 304 g. As described above, drive hub 304 g can comprise, forexample, a resilient material such as a resilient polymer, or any othermaterial permitting the described function. In some embodiments, hub 140j and recess 340 g have dissimilar cross-sectional shapes. For example,in the embodiment shown, hub 140 j has a hexagonal cross-sectional shapeand recess 340 g has a circular cross-sectional shape. In otherembodiments, the driveshaft and recess can have similar cross-sectionalshapes (e.g., hub 140 j can have a circular cross-sectional shape). Tofacilitate insertion of hub 140 j into recess 340 g, one or both of hub140 j and recess 340 g can be tapered (e.g., hub 140 j can have atransverse dimension that is relatively smaller at second end 142 andincreases along a portion of hub 140 j approaching first end 141, and/orrecess 340 g can have a relatively larger transverse dimension (e.g.,diameter) at first end 308 g that increases along a portion of recess340 g approaching second end 312 g). In the embodiment shown, drive hub304 g also includes a recess 324 g configured to receive a portion ofhub 140 j (e.g., a hose fitting with an annular barb, as shown; orLuer-lock fitting threads 148 as in hub 140 a). In other embodiments,recess 324 g can be sized to receive a second hub (not shown butsimilar, for example, to second hub 150 a). In the embodiment shown,recess 324 g is defined by a cylindrical wall 360 g that is, in turn, atleast partially (e.g., up to entirely, as shown) surrounded by a second(e.g., annular) recess 364 g that permits wall 360 g to flex tofacilitate insertion of driveshaft.

FIGS. 10A-10D depict various views of an eighth embodiment 300 h of thepresent couplers in combination with a powered driver 200 h and an IOdevice 100 k that is configured to provide access to an interior of abone (e.g., similar in some respects to IO device 100 c). In theembodiment shown, coupler 300 h comprises a drive hub 304 h having afirst end 308 h and a second end 312 h including a recess 336 hconfigured to receive driveshaft 222 h of driver 200 h. In thisembodiment, second end 312 h is configured such that if driveshaft 222 his inserted into recess 336 h, an interference fit between drive hub 304h and driveshaft 222 h will resist rotation of the drive hub relative tothe driveshaft (and/or resist removal of drive hub 304 h from driveshaft222 h). For example, in the embodiment shown, driveshaft 222 h issubstantially rigid (e.g., comprises a metal such as stainless steel),and drive hub 304 h includes a plurality of tabs or ribs 344 h (e.g.,with a triangular cross-sectional shape, as shown) extending into recess336 h. In this embodiment, tabs 344 e are configured to deform if thedriveshaft is inserted into the recess. In the embodiment shown, recess336 h has at least one transverse dimension that is larger than atransverse dimension of driveshaft 222 h; however, tabs 344 h extendinward and a transverse distance between opposing tabs 344 h is lessthan a transverse dimension of driveshaft 222 h, such that tabs 344 hwill deflect and/or compress and impart a compressive force ondriveshaft 222 h. Drive hub 304 h can comprise, for example, a resilientmaterial such as a resilient polymer, or any other material permittingthe described function. In the embodiment shown, first end 308 h isconfigured to be coupled to IO device 100 k (e.g., to resist rotation ofthe IO device relative to the drive hub). For example, in the embodimentshown, drive hub 304 h is unitary with a portion of hub assembly 130 k(e.g., unitary with second hub 150 k).

Coupler 300 h differs from coupler 300 e, for example, in the drive hub304 h defines a recess 336 h that has a depth that is at least 50%greater (e.g., 100% greater) than the length of driveshaft 222 h that isreceived in recess 336 h, resulting in added length of sidewall 352 h toincrease flexibility of sidewall 352 h and thereby facilitate insertionof driveshaft 222 h into recess 352 h. Driveshaft 222 h differs fromdriveshaft 222 e, for example, in that driveshaft 222 h (e.g., distalend 224 h) comprises one or more (e.g., a plurality of, as shown)projections 368 h extending outward relative to an axis of rotation ofthe driveshaft. In the embodiment shown, projections 368 h areconfigured to be aligned with tabs 344 h, as shown, to deform tabs 344 hto create the interference fit between the driveshaft and the drive hub.In the embodiment shown, recess 336 h has a circular cross-sectionalshape. However, in other embodiments, recess 336 h has a cross-sectionalshape that is similar to the cross-sectional shape of driveshaft 222 h(having a circular central portion and one or more peripheral portions(e.g., corresponding to projections 368 h) extending outwardly from thecircular central portion; and, in such embodiments, tabs 344 h can eachextend into the peripheral portion(s) of the recess). While not shown inFIGS. 10A-10D, other embodiments can comprise a second recess in firstend 308 h with tabs extending into the recess to form an interferencefit with a hub of an IO device (e.g., similar to coupler 100 d).

FIGS. 11A-11D depict various views of a ninth embodiment 300 i of thepresent couplers in combination with a powered driver 200 i and an IOdevice 100 l that is configured to provide access to an interior of abone (e.g., similar in some respects to IO device 100 c). In theembodiment shown, coupler 300 i comprises a drive hub 304 i having afirst end 308 i and a second end 312 i including a recess 336 iconfigured to receive driveshaft 222 i of driver 200 i. In theembodiment shown, coupler 300 i further comprises an adhesive 372 idisposed in the recess and configured to adhere to driveshaft 222 i ifdriveshaft 222 i is inserted into recess 336 i (e.g., to resist (e.g.,interfere with the) removal of driveshaft 222 i from recess 336 i). Inthe embodiment shown, recess 336 i has a cross-sectional shapecorresponding to the cross-sectional shape of driveshaft 222 i such thatif the driveshaft is inserted into the second recess, the drive hub willresist rotating relative to the driveshaft. For example, in theembodiment shown, recess 336 i and driveshaft 222 i each has across-sectional shape of a circle with a portion removed to result intwo opposing flat sides 376 i and 380 i, respectively. Adhesive 372 ican comprise a double-sided tape and/or a liquid or gel adhesivedisposed in the recess (e.g., at sides 376 i and/or at the end of distalend of recess 336 i (farthest from second end 312 i)). In otherembodiments, the driveshaft and recess can have dissimilarcross-sectional shapes (e.g., recess 336 i can have a circularcross-sectional shape). To facilitate insertion of driveshaft 222 i intorecess 336 i, one or both of driveshaft 222 i and recess 336 i can betapered (e.g., driveshaft 222 i can have a transverse dimension that isrelatively smaller at distal end 224 i and increases along a portion ofdriveshaft 222 i approaching housing 210 i, and/or recess 336 i can havea relatively larger transverse dimension (e.g., diameter) at second end312 i that increases along a portion of recess 336 i approaching firstend 308 i). In the embodiment shown, first end 308 i is configured to becoupled to IO device 100 l (e.g., to resist rotation of the IO devicerelative to the drive hub). For example, in the embodiment shown, drivehub 304 i is unitary with a portion of hub assembly 130 l (e.g., unitarywith second hub 150 l).

FIGS. 12A-12D depict various views of a tenth embodiment 300 j of thepresent couplers in combination with a powered driver 200 j and an IOdevice 100 m that is configured for obtaining a sample of bone and/orbone marrow (e.g., similar in some respects to IO devices 100 a and/or100 b). In the embodiment shown, coupler 300 j comprises a drive hub 304j having a first end 308 j and a second end 312 j including a recess 336j configured to receive driveshaft 222 j of driver 200 j. In theembodiment shown, coupler 300 j further comprises an adhesive 372 jdisposed in the recess and configured to adhere to driveshaft 222 j ifdriveshaft 222 j is inserted into recess 336 j (e.g., to resist removalof driveshaft 222 j from recess 336 j). In the embodiment shown, recess336 j has a cross-sectional shape corresponding to the cross-sectionalshape of driveshaft 222 j such that if the driveshaft is inserted intothe second recess, the drive hub will resist rotating relative to thedriveshaft. For example, in the embodiment shown, recess 336 j anddriveshaft 222 j each has a cross-sectional shape of a circle with aportion removed to result in two opposing flat sides 376 j and 380 j,respectively. Further, in this embodiment driveshaft 222 d comprises anenlarged cap member 223 j (on which flats 380 j are disposed) that cancomprise a resilient material (e.g., a resilient polymer) to furtherfacilitate insertion of driveshaft 222 j into recess 336 j. Adhesive 372j can comprise a double-sided tape and/or a liquid or gel adhesivedisposed in the recess (e.g., at sides 376 j and/or at the end of distalend of recess 336 j (farthest from second end 312 j)). In otherembodiments, the driveshaft and the corresponding recess can havedissimilar cross-sectional shapes (e.g., recess 336 j can have acircular cross-sectional shape). To facilitate insertion of driveshaft222 j into recess 336 j, one or both of driveshaft 222 j and recess 336j can be tapered (e.g., driveshaft 222 j can have a transverse dimensionthat is relatively smaller at distal end 224 j and increases along aportion of driveshaft 222 j approaching housing 210 j, and/or recess 336j can have a relatively larger transverse dimension (e.g., diameter) atsecond end 312 j that increases along a portion of recess 336 japproaching first end 308 j).

Drive hub 304 j differs from drive hub 304 i, for example, in that firstend 308 j includes a second recess 340 j that is sized to receive a hub(e.g., first hub 140 m) of IO device 100 m. In the embodiment shown,coupler 300 j further comprises an adhesive 384 j disposed in recess 340j and configured to adhere to hub 140 m if hub 140 m is inserted intorecess 340 j (e.g., to resist removal of IO device 100 m from recess 340j). In the embodiment shown, recess 340 j has a cross-sectional shapecorresponding to the cross-sectional shape of hub 140 m such that if hub140 m is inserted into the second recess, the drive hub will resistrotating relative to hub 140 m. For example, in the embodiment shown,recess 340 j and hub 140 m each has a cross-sectional shape of a circlewith a portion removed to result in two opposing flat sides 388 j and392 j, respectively. Adhesive 384 j can comprise a double-sided tapeand/or a liquid or gel adhesive disposed in the recess (e.g., at sides388 j). In other embodiments, hub 140 m and the corresponding recess canhave dissimilar cross-sectional shapes (e.g., recess 340 j can have acircular cross-sectional shape). To facilitate insertion of hub 140 minto recess 340 j, one or both of hub 140 m and recess 340 j can betapered (e.g., hub 140 m can have a transverse dimension that isrelatively smaller at second end 142 and increases along a portion ofhub 140 m approaching first end 141, and/or recess 340 j can have arelatively larger transverse dimension (e.g., diameter) at first end 308j that increases along a portion of recess 340 j approaching second end312 j). Coupler 300 j further differs from coupler 300 i, for example,in that drive hub 304 j includes a recess 324 j that is sized to receivea second hub (not shown, but similar to second hub 150 a of IO device100 a) in combination with first hub 140 m of IO device 100 m.

FIGS. 13A-13C depict various views of an eleventh embodiment 300 k ofthe present couplers in combination with a powered driver 200 k and anIO device 100 n that is configured to provide access to an interior of abone (e.g., similar in some respects to IO device 100 c). In theembodiment shown, coupler 300 k comprises a drive hub 304 k having afirst end 308 k and a second end 312 k configured to be coupled in fixedrelation to driveshaft 222 k of driver 200 k (e.g., second end 312 k isunitary with driveshaft 222 k in the embodiment shown). In thisembodiment, first end 308 k includes a recess 340 k configured toreceive a portion of hub assembly 130 n (e.g., hub 150 n) of IO device100 n. In the embodiment shown, recess 340 k has a cross-sectional shape(e.g., hexagonal) corresponding to the cross-sectional shape (e.g.,hexagonal) of the portion of the IO device such that if the portion ofthe IO device is inserted into the recess, the drive hub will resistrotation of the IO device relative to the drive hub. To facilitateinsertion of hub 150 n into recess 340 k, one or both of hub 150 n andrecess 340 k can be tapered (e.g., hub 150 n can have a transversedimension that is relatively smaller at second end 142 and increasesalong a portion of hub 150 n approaching first end 141, and/or recess340 k can have a relatively larger transverse dimension (e.g., diameter)at first end 308 k that increases along a portion of recess 340 kapproaching second end 312 k).

FIGS. 14A-14B depict side cross-sectional views of a powered driver 200l for use with at least some embodiments of the present couplers. In theembodiment shown, driver 200 l comprises: a housing 210 l having a bodyportion 213 l and a shroud portion 396 l. In this embodiment, bodyportion 213 l has a sidewall 400 l defining distal end 211 of the bodyportion, and shroud portion 396 l has a cylindrical sidewall 404 lextending from distal end 211 of the body portion. In the embodimentshown, shroud portion 396 l has an open distal end 408 l. In theembodiment shown, driveshaft 222 l has a distal end 224 l extending frombody portion 213 l(e.g., past distal end 211 and into shroud portion 396l). In this embodiment, driver 200 l is configured to be coupled to anIO device (e.g., 100 c) having a hub (e.g., 140 c and/or 150 c) with arecess 186 sized to receive distal end 224 l of the driveshaft, suchthat the distal end of the driveshaft extends into recess 186 and thehub (e.g., 140 c and/or 150 c) of the IO device is at least partiallydisposed in the shroud portion of the housing. For example, in thisembodiment, if IO device 100 c is coupled to driver 200 l, first end 14l of hub 140 c is even with or extends outwardly past distal end 408 l.

FIGS. 15A-15C depict various views of another embodiment of a powereddriver 200 m for use with at least some embodiments of the presentcouplers. Driver 200 m is similar in many respects to driver 200 l, andtherefore the differences in driver 200 m will primarily be describedhere. In the embodiment shown, driver 200 m comprises a plate 412 mhaving an opening 416 m that is disposed in a shroud portion 396 m withdriveshaft 222 m aligned with opening 416 m such that the plate ismovable with shroud portion 396 m along a length of the driveshaft.Shroud portion 396 m that is similar to shroud portion 3961, with theexception that shroud portion 396 m comprises a lip 420 m extendinginward toward the driveshaft and configured to prevent the plate fromexiting the shroud portion, as shown. In this embodiment, driver 200 malso comprises a spring 424 m disposed between plate 412 m and distalend 211 of body portion 213 m of housing 210 m such that the springbiases the plate in a direction toward open end 408 m of the shroudportion.

FIGS. 16A-16C depict various views of a twelfth embodiment 300 n of thepresent couplers in combination with a powered driver 200 n and an IOdevice 100 o that is configured to provide access to an interior of abone (e.g., similar in some respects to IO device 100 c). In theembodiment shown, coupler 300 n comprises a drive hub 304 n having afirst end 308 n and a second end 312 n including a recess 336 nconfigured to receive a driveshaft 222 n of a driver 200 n. In theembodiment shown, coupler 300 n further comprises one or more (e.g.,two, as shown) resilient clips 428 n biased toward an axis of rotationof the drive hub (e.g., and of driveshaft 222 n). For example, in thisembodiment, coupler 300 n comprises a hollow sleeve 332 n configured tobe disposed around recess 336 n such that driveshaft 222 n, if insertedinto the recess, will also be disposed in the hollow sleeve. In thisembodiment, resilient clips 428 n are unitary with sleeve 432 n (e.g.,comprise a single piece of sheet metal). As described above for otherembodiments, recess 336 n has a cross-sectional shape corresponding tothe cross-sectional shape of driveshaft 222 n such that if thedriveshaft is inserted into the recess, drive hub 304 n will resistrotating relative to the driveshaft. For example, in this embodiment,both of recess 336 n and driveshaft 222 n have non-circular (e.g.,elongated) cross-sectional shapes. In the embodiment shown, first end308 n is configured to be coupled to IO device 100 o (e.g., to resistrotation of the IO device relative to the drive hub). For example, inthe embodiment shown, drive hub 304 n is unitary with a portion of a hubassembly (e.g., unitary with second hub 1500).

FIGS. 17A-17D depict various views of a thirteenth embodiment 300 o ofthe present couplers in combination with a powered driver 200 o and anIO device 100 p that is configured to provide access to an interior of abone (e.g., similar in some respects to IO device 100 c). In theembodiment shown, coupler 300 o comprises a drive hub 304 o having afirst end 308 o and a second end 312 o configured to be coupled in fixedrelation to a driveshaft 222 o of driver 200 o (e.g., drive hub 304 ocan be unitary with driveshaft 222 o, as shown). In this embodiment,first end 308 o includes a recess 340 o configured to receive a hub(e.g., second hub 150 p) of IO device 100 p. In the embodiment shown,drive hub 304 o has a sidewall 436 o with at least one (e.g., two, asshown) opening 440 o extending through the sidewall in communicationwith recess 340 o. In this embodiment, each opening 440 o has an innercross-sectional area at recess 340 o that is smaller than an outercross-sectional area spaced apart from the inner cross-sectional area.In the embodiment shown, coupler 300 o also comprises a ball 444 omovably disposed in each opening 440 o; and a resilient c-clip 448 odisposed around the drive hub such that c-clip 448 o biases ball(s) 444o toward a rotational axis of the drive hub (and of the driveshaft). Inthe embodiment shown, ball(s) 444 o each has a maximum cross-sectionalarea that is larger than the inner cross-sectional area of therespective opening 440 o to prevent the ball from falling into recess340 o if driveshaft 222 o is not disposed in recess 340 o. In thisembodiment, second end 312 o of drive hub 304 o is configured such thatif a hub (e.g., second hub 150 p) of IO device 100 p (which, in thisembodiment, has at least one detent 452 o configured to align withopenings 440 o) is inserted into recess 340 o, the c-clip will: (i)allow ball(s) 444 o to move away from the rotational axis of the drivehub until detent(s) 452 o align with ball(s) 444 o, and (ii) pressball(s) 444 o into detent(s) 452 o when detent(s) 452 o align withball(s) 444 o to resist removal of the driveshaft from the recess. Insome embodiments, hub 150 p and/or recess 340 o have non-circularcross-sectional shapes (e.g., to resist rotation of hub 150 p relativedrive hub 304 o). In the embodiment shown, drive hub 304 o has acircular outer cross-sectional shape. In the embodiment shown, hub 150 pincludes a projection 456 o that includes detent(s) 452 o.

FIGS. 18A-18C depict various views of a fourteenth embodiment 300 p ofthe present couplers in combination with a powered driver 200 p and anIO device 100 q that is configured for obtaining a sample of bone and/orbone marrow (e.g., similar in some respects to IO devices 100 a and/or100 b). In the embodiment shown, coupler 300 p comprises a drive hub 304p having a first end 308 p and a second end 312 p configured to becoupled in fixed relation to a driveshaft 222 p of driver 200 p (e.g.,drive hub 304 p can be unitary with driveshaft 222 p, as shown). In thisembodiment, first end 308 p includes a recess 340 p configured toreceive a hub (e.g., first hub 140 q) of IO device 100 q. In theembodiment shown, drive hub 304 p has a sidewall 436 p with at least one(e.g., two, as shown) opening 440 p extending through the sidewall incommunication with recess 340 p. In this embodiment, each opening 440 phas an inner cross-sectional area at recess 340 p that is smaller thanan outer cross-sectional area spaced apart from the innercross-sectional area. In the embodiment shown, coupler 300 p alsocomprises a ball 444 p movably disposed in each opening 440 p; and aresilient c-clip 448 p disposed around the drive hub such that c-clip448 p biases ball(s) 444 p toward a rotational axis of the drive hub(and of the driveshaft). In the embodiment shown, ball(s) 444 p each hasa maximum cross-sectional area that is larger than the innercross-sectional area of the respective opening 440 p to prevent the ballfrom falling into recess 340 p if hub 140 q is not disposed in recess340 p. In this embodiment, second end 312 p of drive hub 304 p isconfigured such that if a hub (e.g., first hub 140 q) of IO device 100 q(which, in this embodiment, has at least one detent 452 q configured toalign with openings 440 p) is inserted into recess 340 p, the c-clipwill: (i) allow ball(s) 444 p to move away from the rotational axis ofthe drive hub until detent(s) 452 p align with ball(s) 444 p, and (ii)press ball(s) 444 p into detent(s) 452 p when detent(s) 452 p align withball(s) 444 p to resist removal of hub 140 q from the recess. In someembodiments, hub 140 q and/or recess 340 p have non-circularcross-sectional shapes (e.g., to resist rotation of hub 140 q relativeto drive hub 304 p). In the embodiment shown, drive hub 304 p has acircular outer cross-sectional shape.

Coupler 300 p differs from coupler 300 o, for example, in that first end308 p includes a recess 336 p configured to receive driveshaft 222 p ofdriver 200 p. In the embodiment shown, drive hub 304 p has a sidewall460 p with at least one (e.g., two, as shown) opening 464 p extendingthrough the sidewall in communication with recess 336 p, with eachopening 464 p having an inner cross-sectional area at recess 336 p thatis smaller than an outer cross-sectional area spaced apart from theinner cross-sectional area (e.g., at the outer surface of sidewall 460p). In the embodiment shown, coupler 300 p also comprises at least one(e.g., two, as shown) second ball 468 p each movably disposed in anopening 464 p; and a second resilient c-clip 472 p disposed around thedrive hub such that the c-clip biases ball(s) 468 p toward a rotationalaxis of the drive hub (and of the driveshaft). In the embodiment shown,ball(s) 468 p each has a maximum cross-sectional area that is largerthan the inner cross-sectional area of the respective opening 464 p toprevent the ball from falling into recess 336 p if driveshaft 222 p isnot disposed in recess 340 p. In this embodiment, second end 312 p ofthe drive hub is configured such that if driveshaft 222 p (which has atleast one detent 476 p) is inserted into recess 336 p, the c-clip will:(i) allow ball(s) 468 p to move away from the rotational axis of thedrive hub until detent(s) 476 p aligns with ball(s) 468 p, and (ii)press ball(s) 468 p into detent(s) 476 p when detent(s) 476 p align withball(s) 468 p to resist removal of the driveshaft from the recess. Insome embodiments, driveshaft 222 p and/or recess 336 p have non-circularcross-sectional shapes (e.g., to resist rotation of drive hub 304 prelative to driveshaft 222 p). In the embodiment shown, drive hub 304 phas a circular outer cross-sectional shape. Coupler 300 p furtherdiffers from coupler 300 o, for example, in that drive hub 304 pincludes a recess 324 p that is sized to receive a second hub (notshown, but similar to second hub 150 a of IO device 100 a).

FIGS. 19A-19C depict various views of a fifteenth embodiment 300 q ofthe present couplers in combination with a powered driver 200 q and anIO device 100 r that is configured to provide access to an interior of abone (e.g., similar in some respects to IO device 100 c). In theembodiment shown, coupler 300 q comprises a drive hub 304 q having afirst end 308 q and a second end 312 q configured to be coupled in fixedrelation to a driveshaft 222 q of driver 200 q (e.g., drive hub 304 qcan be unitary with driveshaft 222 q, as shown). In this embodiment,first end 308 q includes a recess 340 q configured to receive a hub(e.g., second hub 150 r) of IO device 100 r. In the embodiment shown,drive hub 304 q has a sidewall 436 q with at least one (e.g., two, asshown) opening 440 q extending through the sidewall in communicationwith recess 340 q. In this embodiment, each opening 440 q has an innercross-sectional area at recess 340 q that is smaller than an outercross-sectional area spaced apart from the inner cross-sectional area.In the embodiment shown, coupler 300 q also comprises a ball 444 qmovably disposed in each opening 440 q; and a collar 480 q movablydisposed around the drive hub and having an interior surface 484 qdefining at least one detent 488 q adjacent the drive hub. In thisembodiment, collar 480 q is movable between: (i) a first position (FIG.19B) in which detent(s) 488 q of collar 480 q is aligned with opening(s)440 q such that ball(s) 444 q can move away from the rotational axis ofthe drive hub to permit a hub (e.g., 150 r) of IO device 100 r having adetent 352 q to be inserted into or removed from recess 340 q (thisfirst position and other such similar positions described in thisdisclosure may also be characterized as positions that allow the hub tomove within the recess without interference from the positive detentingstructure (e.g., ball 444 q in this embodiment), and (ii) a secondposition (FIG. 19C) in which detent(s) 488 q of collar 480 q do notalign with opening(s) 440 q such that if a hub (e.g., 150 r) of IOdevice 100 r having detent(s) 352 q is disposed in recess 340 q suchthat detent(s) 352 q of hub 150 r align with opening(s) 440 q, IO device100 r is prevented from being removed from recess 340 q (this secondposition and other such similar positions described in this disclosuremay also be characterized as positions that cause the positive detentingstructure (e.g., ball 444 q in this embodiment) to be sufficientlydisposed in the detent (e.g., detent(s) 352 q in this embodiment) suchthat the hub cannot move completely in and out of the recess due tointerference with the positive detenting structure). In someembodiments, hub 150 r and/or recess 340 q have non-circularcross-sectional shapes (e.g., to resist rotation of hub 150 r relativeto drive hub 304 q). In the embodiment shown, hub 150 r includes aprojection 356 q that includes detent(s) 352 q. In the embodiment shown,coupler 300 q comprises a spring 492 q that biases collar 480 q towardthe second position (FIG. 19C). While not shown in FIGS. 19A-19D, otherembodiments can comprise a second recess in second end 312 q withopenings, balls, and a second collar to engage corresponding detents ina driveshaft of a driver (e.g., similar to coupler 300 p).

FIGS. 20A-20B depict side cross-sectional views of a sixteenthembodiment 300 r of the present couplers in combination with a powereddriver 200 r and an IO device 100 s that is configured to provide accessto an interior of a bone (e.g., similar in some respects to IO device100 c). In the embodiment shown, coupler 300 r comprises a drive hub 304r having a first end 308 r and a second end 312 r configured to becoupled in fixed relation to a driveshaft 222 r of driver 200 r (e.g.,drive hub 304 r can be unitary with driveshaft 222 r, as shown). In thisembodiment, first end 308 r includes a recess 340 r configured toreceive a hub 130 s (e.g., second hub 150 s) of IO device 100 s. In theembodiment shown, drive hub 304 r has a sidewall 436 r with at least one(e.g., two, as shown) opening 440 r extending through the sidewall incommunication with recess 340 r. In the embodiment shown, coupler 300 ralso comprises at least one set screw 496 r with a spring-loaded ball444 r, with set screw(s) 496 r disposed in opening(s) 440 r such thatball 440 r is biased in a direction toward an axis of rotation of thedrive hub. In this embodiment, second end 312 r of drive hub 304 r isconfigured such that if a hub (e.g., hub 150 s) of IO device 100 shaving at least one detent 452 r is inserted into recess 340 r: (i)spring-loaded ball(s) 444 r will move away from the rotational axis ofthe drive hub until detent(s) 452 r align with ball(s) 444 r, and (ii)ball(s) 444 r will move into detent(s) 452 r when detent(s) align withball(s) 444 r to resist removal of the IO device from recess 340 r. Insome embodiments, hub 150 s and/or recess 340 s have non-circularcross-sectional shapes (e.g., to resist rotation of hub 150 s relativeto drive hub 304 r). In the embodiment shown, hub 150 s includes aprojection 456 r that includes detent(s) 452 r.

FIGS. 21A-21C depict various views of a seventeenth embodiment 300 s ofthe present couplers in combination with a powered driver 200 s and anIO device 100 t that is configured for obtaining a sample of bone and/orbone marrow (e.g., similar in some respects to IO devices 100 a and/or100 b). In the embodiment shown, coupler 300 s comprises a drive hub 304s having a first end 308 s and a second end 312 s configured to becoupled in fixed relation to a driveshaft 222 s of driver 200 s. In thisembodiment, first end 308 s includes a recess 340 s configured toreceive a hub (e.g., first hub 140 t) of IO device 100 t. In theembodiment shown, drive hub 304 s has a sidewall 436 s, a distal portionof which has at least one (e.g., two, as shown) opening 440 s extendingthrough the sidewall in communication with recess 340 s. In theembodiment shown, coupler 300 s also comprises at least one set screw496 s with a spring-loaded ball 444 s (these and others like them inthis disclosure may also be characterized collectively as aspring-loaded ball plunger and a set screw), with set screw(s) 496 sdisposed in opening(s) 440 s such that ball 444 s is biased in adirection toward an axis of rotation of the drive hub. In thisembodiment, second end 312 s of drive hub 304 s is configured such thatif a hub (e.g., hub 140 t) of IO device 100 t having at least one detent352 s is inserted into recess 340 s: (i) spring-loaded ball(s) 444 swill move away from the rotational axis of the drive hub until detent(s)352 s align with ball(s) 444 s, and (ii) ball(s) 444 s will move intodetent(s) 352 s when detent(s) align with ball(s) 444 s to resistremoval of the IO device from recess 340 s. In some embodiments, hub 140t and/or recess 340 s have non-circular cross-sectional shapes (e.g., toresist rotation of hub 140 t relative to drive hub 304 s). In theembodiment shown, hub 140 t includes a projection 456 s that includesdetent(s) 452 s.

Coupler 300 s differs from coupler 300 r, for example, in that secondend 312 s includes a recess 336 s configured to receive driveshaft 222 sof driver 200 s. In the embodiment shown, a proximal portion of sidewall3460 s (the proximal portion having a cross-sectional area that issmaller than a cross-sectional area of the distal portion referencedabove) has at least one (e.g., two, as shown) opening 464 s extendingthrough the sidewall in communication with recess 336 s. In theembodiment shown, coupler 300 s also comprises at least one set screw496 s with a spring loaded ball 444 s, with set screw(s) 496 s disposedin opening(s) 464 s such that ball(s) 444 s are biased in a directiontoward an axis of rotation of the drive hub. In this embodiment, secondend of drive hub 304 s is configured such that if driveshaft 222 s(which has at least one detent 476 s) is inserted into recess 336 s: (i)ball(s) 444 s of screw(s) 496 s will move away from the rotational axisof the drive hub until detent(s) 476 s aligns with ball(s) 444 s, and(ii) ball(s) 444 s of screw(s) 496 s will move into detent(s) 476 s whendetent(s) 476 s align with ball(s) 444 s to resist removal of driveshaft222 s from recess 336 s. In some embodiments, driveshaft 222 s and/orrecess 336 s have non-circular cross-sectional shapes (e.g., to resistrotation of drive hub 304 s relative to driveshaft 222 s). In theembodiment shown, drive hub 304 s has a circular outer cross-sectionalshape. Coupler 300 s further differs from coupler 300 r, for example, inthat drive hub 304 s includes a recess 324 s that is sized to receive asecond hub (not shown, but similar to second hub 150 a of IO device 100a).

FIGS. 22A-22B depict side cross-sectional views of an eighteenthembodiment 300 t of the present couplers in combination with a powereddriver 200 t and an IO device 100 u that is configured to provide accessto an interior of a bone (e.g., similar in some respects to IO device100 c). In the embodiment shown, coupler 300 t comprises a drive hub 304t having a first end 308 t and a second end 312 t configured to becoupled in fixed relation to a driveshaft 222 t of driver 200 t (e.g.,drive hub 304 t can be unitary with driveshaft 222 t, as shown). In thisembodiment, first end 308 t includes a recess 340 t configured toreceive a hub (e.g., second hub 150 u) of IO device 100 u. In theembodiment shown, drive hub 304 t has a sidewall 436 t with at least oneopening 440 t extending through the sidewall in communication withrecess 340 t. In the embodiment shown, coupler 300 t also comprises ascrew 500 t having an enlarged head 504 t and a threaded shaft 508 twith a distal end 512 t, the screw threaded into opening 440 t with thedistal end facing in a direction toward an axis of rotation of the drivehub. In this embodiment, screw 500 t is rotatable between: (i) a firstposition in which distal end 512 t does not extend into recess 340 t topermit hub 150 u of IO device 100 u having a detent 452 t to be insertedinto or removed from recess 340 t; and (ii) a second position in whichdistal end 512 t extends into second recess 340 t such that if hub 150 uof IO device 100 u having detent(s) 452 t is disposed in recess 340 tsuch that detent 452 t is aligned with opening 440 t (and thereby screw500 t), IO device 100 u is prevented from being removed from recess 340t (e.g., as shown in FIG. 22B). In some embodiments, hub 150 u and/orrecess 340 t have non-circular cross-sectional shapes (e.g., to resistrotation of hub 150 u relative to drive hub 304 t). In the embodimentshown, hub 150 u includes a projection 456 t that includes detent(s) 452t.

FIGS. 23A-23B depict perspective and side cross-sectional views,respectively, of a nineteenth embodiment 300 u of the present couplersin combination with a powered driver 200 u and an IO device 100 v thatis configured for obtaining a sample of bone and/or bone marrow (e.g.,similar in some respects to IO devices 100 a and/or 100 b). In theembodiment shown, coupler 300 u comprises a drive hub 304 u having afirst end 308 u and a second end 312 u configured to be coupled in fixedrelation to a driveshaft 222 u of driver 200 u (e.g., drive hub 304 ucan be unitary with driveshaft 222 u, as shown). In this embodiment,first end 308 u includes a recess 340 u configured to receive a hub(e.g., first hub 140 v) of IO device 100 v. In the embodiment shown,drive hub 304 u has a sidewall 436 u, a distal portion of which has atleast one opening 440 u extending through the sidewall in communicationwith recess 340 u. In the embodiment shown, coupler 300 u also comprisesa screw 500 u having an enlarged head 504 u and a threaded shaft 508 uwith a distal end 512 u, the screw threaded into opening 440 u with thedistal end facing in a direction toward an axis of rotation of the drivehub. In this embodiment, screw 500 u is rotatable between: (i) a firstposition in which distal end 512 u does not extend into recess 340 u topermit hub 130 v (e.g., hub 150 v) of IO device 100 v having a detent452 u to be inserted into or removed from recess 340 u; and (ii) asecond position in which distal end 512 u extends into second recess 340u such that if hub 150 v of IO device 100 v having detent(s) 452 u isdisposed in recess 340 u such that detent 452 u is aligned with opening440 u (and thereby screw 500 u), IO device 100 v is prevented from beingremoved from recess 340 u (e.g., as shown in FIG. 23B). In someembodiments, hub 150 v and/or recess 340 u have non-circularcross-sectional shapes (e.g., to resist rotation of hub 150 v relativeto drive hub 304 u). In the embodiment shown, hub 150 v includes aprojection 456 u that includes detent(s) 452 u.

Coupler 300 u differs from coupler 300 t, for example, in that secondend 312 u includes a recess 336 u configured to receive driveshaft 222 uof driver 200 u. In the embodiment shown, a proximal portion of sidewall346 u (the proximal portion having a cross-sectional area that issmaller than a cross-sectional area of the distal portion referencedabove) has at least one (e.g., two, as shown) opening 464 u extendingthrough the sidewall in communication with recess 336 u. In theembodiment shown, coupler 300 u also comprises a second screw 500 uhaving an enlarged head 504 u and a threaded shaft 508 u with a distalend 512 u, the second screw threaded into opening 464 u with the distalend facing in a direction toward an axis of rotation of the drive hub.In this embodiment, the second screw is rotatable between: (i) a firstposition in which distal end 512 u does not extend into recess 336 u topermit driveshaft 222 u (which has a detent 476 u) to be inserted intoor removed from recess 336 u, and (ii) a second position in which distalend 512 u extends into recess 336 u such that if driveshaft 222 u havingdetent 476 u is disposed in recess 336 u such that detent 476 u isaligned with opening 464 u (and thereby screw 500 u), driveshaft 222 uis prevented from being removed from recess 336 u. In some embodiments,driveshaft 222 u and/or recess 336 u have non-circular cross-sectionalshapes (e.g., to resist rotation of drive hub 304 u relative todriveshaft 222 u). Coupler 300 u further differs from coupler 300 t, forexample, in that drive hub 304 u includes a recess 324 u that is sizedto receive a second hub (not shown, but similar to second hub 150 a ofIO device 100 a).

FIGS. 24A-24B depict perspective and side cross-sectional views,respectively, of a twentieth embodiment of the present couplers 300 v incombination with a powered driver 200 v and an IO device 100 w that isconfigured to provide access to an interior of a bone (e.g., similar insome respects to IO device 100 c). In the embodiment shown, coupler 300v comprises a drive hub 304 v having a first end 308 v and a second end312 v configured to be coupled in fixed relation to a driveshaft 222 vof driver 200 v (e.g., drive hub 304 v can be unitary with driveshaft222 v, as shown). In this embodiment, first end 308 v includes a recess340 v configured to receive a hub (e.g., second hub 150 w) of IO device100 w. In the embodiment shown, drive hub 304 v has a sidewall 436 vwith at least one (e.g., two, as shown) opening 440 v extending throughthe sidewall in communication with recess 340 v. In the embodimentshown, coupler 300 v also comprises a pin 520 v having a distal end 524v configured to be inserted into opening 440 v such that pin 520 vextends across a majority (e.g., all) of a width of recess 340 v (e.g.,and through a second opening 440 v on an opposite side of opening 340 v,as shown). In this embodiment, pin 520 v is movable between: (i) a firstposition in which distal end 524 v does not extend into recess 340 v topermit a hub 150 w of IO device 100 w (which has a transverse passageway528 w) to be inserted into or removed from recess 340 v, and (ii) asecond position in which pin 520 v extends into and across a majority(e.g., all) of recess 340 v (as shown in FIG. 24B) such that if hub 150w of IO device 100 v having transverse passageway 528 w is disposed inrecess 340 v such that transverse passageway 528 w is aligned withopening 440 v, pin 520 v extends into (e.g., through) transversepassageway 528 w to prevent IO device 100 w from being removed fromrecess 340 v. In some embodiments, such as the one shown, hub 150 wand/or recess 340 v have non-circular cross-sectional shapes (e.g., toresist rotation of hub 150 w relative to drive hub 304 v). In theembodiment shown, hub 150 w includes a projection 456 v that includestransverse passageway 528 w.

FIGS. 25A-25B depict perspective and side cross-sectional views,respectively, of a twenty-first embodiment 300 w of the present couplersin combination with a powered driver 200 w and an IO device 100 x thatis configured for obtaining a sample of bone and/or bone marrow (e.g.,similar in some respects to IO devices 100 a and/or 100 b). In theembodiment shown, coupler 300 w comprises a drive hub 304 w having afirst end 308 w and a second end 312 w configured to be coupled in fixedrelation to a driveshaft 222 w of driver 200 w. In this embodiment,first end 308 w includes a recess 340 w configured to receive a hub(e.g., first hub 140 x) of IO device 100 x. In the embodiment shown,drive hub 304 w has a sidewall 436 w, a distal portion of which has atleast one (e.g., two, as shown) opening 440 w extending through thesidewall in communication with recess 340 w. In the embodiment shown,coupler 300 w also comprises a pin 520 w having a distal end 524 wconfigured to be inserted into opening 440 w such that pin 520 w extendsacross a majority (e.g., all) of a width of recess 340 w (e.g., andthrough a second opening 440 w on an opposite side of opening 340 w, asshown). In this embodiment, pin 520 w is movable between: (i) a firstposition in which distal end 524 w does not extend into recess 340 w topermit a hub 150 x (e.g., hub 130 x) of IO device 100 x (which has atransverse passageway 528 x) to be inserted into or removed from recess340 w, and (ii) a second position in which pin 520 w extends into andacross a majority (e.g., all) of recess 340 w (as shown in FIG. 25B)such that if hub 150 x of IO device 100 x having transverse passageway528 x is disposed in recess 340 w such that transverse passageway 528 xis aligned with opening 440 w, pin 520 w extends into (e.g., through)transverse passageway 528 x to prevent IO device 100 x from beingremoved from recess 340 w. In some embodiments, such as the one shown,hub 150 x and/or recess 340 w have non-circular cross-sectional shapes(e.g., to resist rotation of hub 150 x relative to drive hub 304 x). Inthe embodiment shown, hub 150 x includes a projection 456 w thatincludes transverse passageway 528 x.

Coupler 300 w differs from coupler 300 v, for example, in that secondend 312 w includes a recess 336 w configured to receive driveshaft 222 wof driver 200 w. In the embodiment shown, a proximal portion of sidewall436 w of drive hub 304 w (the proximal portion having a cross-sectionalarea that is smaller than a cross-sectional area of the distal portionreferenced above) includes at least one (e.g., two, as shown) opening464 w extending through the sidewall in communication with recess 336 w.In the embodiment shown, coupler 300 w also comprises a second a pin 520w having a distal end 524 w configured to be inserted into opening 464 wsuch that pin 520 w extends across a majority (e.g., all) of a width ofrecess 340 w (e.g., and through a second opening 464 w on an oppositeside of opening 340 v, as shown). In this embodiment, pin 520 v ismovable between: (i) a first position in which distal end 524 w does notextend into recess 336 w to permit a driveshaft 222 w driver 200 w(which has a transverse passageway 532 w) to be inserted into or removedfrom recess 336 w, and (ii) a second position in which pin 520 w extendsinto and across a majority (e.g., all) of recess 340 w (as shown in FIG.25B) such that if driveshaft 222 w of driver 200 w having transversepassageway 532 w is disposed in recess 336 w such that transversepassageway 532 w is aligned with opening 464 w, pin 520 w extends into(e.g., through) transverse passageway 532 w to prevent IO device 100 xfrom being removed from recess 336 w. In some embodiments, such as theone shown, driveshaft 222 w and/or recess 336 w have non-circularcross-sectional shapes (e.g., to resist rotation of drive hub 304 wrelative to driveshaft 222 w). Coupler 300 w also differs from coupler300 v, for example, in that drive hub 304 w includes a recess 324 w thatis sized to receive a second hub (not shown, but similar to second hub150 a of IO device 100 a).

FIGS. 26A-26E depict various views of a twenty-second embodiment 300 xof the present couplers in combination with a powered driver 200 x andan IO device 100 y that is configured to provide access to an interiorof a bone (e.g., similar in some respects to IO device 100 c). In theembodiment shown, driver 200 x is similar in some respects to driver 200l described above with reference to FIGS. 14A-14B. For example, driver200 x comprises a housing 210 x having a body portion 213 x and a shroudportion 396 x. In this embodiment, body portion 213 x has a sidewall 400x defining distal end 211 of the body portion, and shroud portion 396 xhas a cylindrical sidewall 404 x extending from distal end 211 of thebody portion. In the embodiment shown, shroud portion 396 x has an opendistal end 408 x. In the embodiment shown, driveshaft 222 x has a distalend 224 x extending from body portion 213 x (e.g., past distal end 211and into shroud portion 396 x). However, driver 200 x differs fromdriver 200 l, for example, in that shroud portion 396 x includes one ormore (e.g., two, as shown) projections 536 x extending (e.g., inopposite directions) from sidewall 404 x (e.g., and away from driveshaft222 x). In this embodiment, projections 536 x are shaped as short,circular cylinders.

In the embodiment shown, coupler 300 x comprises a hollow sleeve 544 xconfigured to be rotatably coupled to a hub (e.g., a first hub and/or asecond hub) of IO device 100 y. In this embodiment, sleeve 544 xincludes a proximal portion 548 x configured to fit over shroud portion396 x of housing 210 x (as shown, for example, in FIG. 26B) to couplethe IO device to the driver and resist removal of IO device from thedriver. In this embodiment, proximal portion 548 x of sleeve 544 xcomprises one or more (e.g., two, as shown) L-shaped slots 552 x eachconfigured to receive a projection 536 x if proximal portion 544 x ofthe sleeve is disposed over shroud portion 396 x such that sleeve 544 xcan be rotated in direction 556 x relative to shroud portion 396 x toresist removal of the IO device from the driver (e.g., to lock thesleeve relative to the driver by seating projections 536 x in laterallegs 560 x of slots 552 x, as shown in FIG. 26E). In this embodiment,distal end 561 x of sleeve 544 x includes an openings 564 x (e.g., witha circular cross-section, as shown) through which a portion of IO device100 y can extend such that the driver can rotate the IO device whilesleeve 544 x is coupled in fixed relation to the driver. In theembodiment shown, IO device 100 y comprises an elongated hub assembly130 y having a first end 131 with a circular cross-section sized tocorrespond to that of opening 564 x (e.g., that is smaller than aportion of hub 130 y configured to be disposed immediately inside sleeve544 x). In this embodiment, hub 130 y also comprises a flange 568 x witha circular cross-section that is larger than opening 564 x such thatfirst end 131 can “snap” into opening 564 x to (i) maintain itslongitudinal position relative to sleeve 544 x, (ii) create a tortuouspath through opening to reduce the likelihood of contaminants travelingthrough opening 546 x while IO device 100 y is coupled to sleeve 544 x,and (iii) permit IO device 100 y to rotate relative sleeve 544 x.

FIGS. 27A-27C depict various views of a twenty-third embodiment 300 y ofthe present couplers in combination with a powered driver 200 y and IOdevice 100 z that is configured to provide access to an interior of abone (e.g., similar in some respects to IO device 100 c). In theembodiment shown, driver 200 y is similar in some respects to driver 200x. For example, driver 200 y comprises a housing 210 y having a bodyportion 213 y and a shroud portion 396 y. In this embodiment, bodyportion 213 y has a sidewall 400 y defining distal end 211 of the bodyportion, and shroud portion 396 y has a cylindrical sidewall 404 yextending from distal end 211 of the body portion. In the embodimentshown, shroud portion 396 y has an open distal end 408 y. In theembodiment shown, driveshaft 222 y has a distal end 224 y extending frombody portion 213 y past distal end 211 and into shroud portion 396 y. Inthe embodiment shown, shroud portion 396 y includes one or more (e.g.,two, as shown) projections 536 y extending (e.g., in oppositedirections) from sidewall 404 y (e.g., and away from driveshaft 222 y).Driver 200 y differs from driver 200 x, for example, in that shroudportion 396 y (e.g., sidewall 404 y) comprises one or more (e.g., two,as shown) resilient portions 572 y and one or more substantially rigidportions 576 y, with projections 536 y extending from resilient portions572 y such that the projections are movable relative to driveshaft 222y. In this embodiment, resilient portions 572 y and substantially rigidportions 576 y comprise the same material, and resilient portions arecreated by the placement of slots 580 y between portions 572 y and 576 ysuch that resilient portions 572 y have less curvature thansubstantially rigid portions 576 y, and thereby have less resistance atdistal end 408 y to bending toward driveshaft 222 y (but still enoughresistance to bending to bias resilient portions 572 y toward a positionin which portions 572 y are substantially aligned with portions 576 y).

In the embodiment shown, coupler 300 y comprises a hollow sleeve 544 yconfigured to be rotatably coupled to a hub 130 z (e.g., first hub 140 zand/or second hub 150 z) of IO device 100 z. In this embodiment, sleeve544 y includes a proximal portion 548 y configured to fit over shroudportion 396 y of housing 210 y (as shown, for example, in FIG. 27B) tocouple the IO device to the driver and resist removal of IO device fromthe driver. In this embodiment, proximal portion 548 y includes aninterior surface 584 y defining one or more detents 588 y configured toreceive projections 536 y of shroud portion 396 y to resist removal ofthe IO device from the driver. In this embodiment, sleeve 544 y can bepressed directly over shroud portion 396 y (e.g., FIG. 27B to FIG. 27C)such that proximal portion 548 y will depress projections 536 y (andresilient portions 572 y) until detent(s) 588 y align with detent(s) 588y, at which point, resilient portions 572 y will return to their restingpositions and extend projections 536 y into detent(s) 588 y. In thisembodiment, distal end 560 y of sleeve 544 y includes an openings 564 y(e.g., with a circular cross-section, as shown) through which a portionof IO device 100 z can extend such that the driver can rotate the IOdevice while sleeve 544 y is coupled in fixed relation to the driver. Inthe embodiment shown, IO device 100 z comprises an elongated hubassembly 130 z having a first end 131 with a circular cross-sectionsized to correspond to that of opening 564 y (e.g., that is smaller thana portion of hub 130 z configured to be disposed immediately insidesleeve 544 x). In this embodiment, hub 130 z also comprises a flange 568y with a circular cross-section that is larger than opening 564 y suchthat first end 131 can “snap” into opening 564 y to (i) maintain itslongitudinal position relative to sleeve 544 y, (ii) create a tortuouspath through opening to reduce the likelihood of contaminants travelingthrough opening 546 y while IO device 100 z is coupled to sleeve 544 y,and (iii) permit IO device 100 z to rotate relative sleeve 544 y.

FIGS. 28A-28C depict various views of a twenty-fourth embodiment 300 zof the present couplers in combination with a powered driver 200 z andan IO device 100 aa that is configured to provide access to an interiorof a bone (e.g., similar in some respects to IO device 100 c). In theembodiment shown, driver 200 z is similar in some respects to driver 200y. For example, driver 200 z comprises: a housing 210 z having a bodyportion 213 z and a shroud portion 396 z. In this embodiment, bodyportion 213 z has a sidewall 400 z defining distal end 211 of the bodyportion, and shroud portion 396 z has a cylindrical sidewall 404 zextending from distal end 211 of the body portion. In the embodimentshown, shroud portion 396 z has an open distal end 408 z. In theembodiment shown, driveshaft 222 z has a distal end 224 z extending frombody portion 213 z past distal end 211 and into shroud portion 396 z).In the embodiment shown, shroud portion 396 z includes one or more(e.g., two, as shown) projections 536 z extending (e.g., in oppositedirections) from sidewall 404 z (e.g., and away from driveshaft 222 z).Driver 200 z differs from driver 200 y, for example, in that shroudportion 396 z (e.g., sidewall 404 z) comprises one includes twoelongated grooves 592 z in an outer surface of cylindrical sidewall 404z, with grooves 592 z extending in a direction that is substantiallyperpendicular to the rotational axis of the driveshaft, as shown. Inother embodiments, grooves 592 z can be disposed or orientated at anysuitable angle relative to driveshaft 222 z.

In the embodiment shown, coupler 300 z comprises a hollow sleeve 544 zconfigured to be rotatably coupled to a hub (e.g., a first hub and/or asecond hub) of IO device 100 aa. In this embodiment, sleeve 544 zincludes a proximal portion 548 z configured to fit over shroud portion396 z of housing 210 z (as shown, for example, in FIG. 28B) to couplethe IO device to the driver and resist removal of IO device from thedriver. In this embodiment, proximal portion 548 z of the sleevecomprises two elongated openings 596 z that are configured to align withgrooves 592 z in shroud portion 396 z if proximal portion 548 z isdisposed on shroud portion 396 z. In this embodiment, coupler 300 z alsocomprises a resilient U-shaped clip 600 z having two legs 604 z, andclip 600 z is configured to extend over proximal portion 548 z with legs604 z extending through elongated openings 596 z and into elongatedgrooves 592 z to resist removal of the sleeve and IO device from thedriver (as shown in FIGS. 28B and 28C).

FIGS. 29A-29D depict various views of a twenty-fifth embodiment of thepresent couplers 300 aa in combination with a powered driver 200 aa andan IO device 100 bb that is configured to provide access to an interiorof a bone (e.g., similar in some respects to IO device 100 c). In theembodiment shown, coupler 300 aa comprises a drive hub 304 aa having afirst end 308 aa and a second end 312 aa configured to be coupled infixed relation to driveshaft 222 aa of a driver 200 aa (e.g., second end312 aa is unitary with driveshaft 222 aa in the embodiment shown). Inthe embodiment shown, coupler 300 aa also comprises a resilient clamp608 aa having a substantially circular interior 612 aa, and configuredto be movable between (i) a contracted position (FIG. 29C) in which theinterior has a first transverse dimension 616 aa, and (ii) an expandedposition (FIG. 29D) in which the interior has a second transversedimension 620 aa that is larger than first transverse dimension 616 aa.In this embodiment, clamp 608 aa is biased toward the contractedposition of FIG. 29C. In the embodiment shown, drive hub 304 aa has atransverse dimension 624 aa that is larger than dimension 616 aa andthat is larger than a transverse dimension (e.g., diameter) ofdriveshaft 222 a. In this embodiment, first end 308 aa of drive hub 304aa is configured to abut IO device 100 bb (e.g., a hub 150 bb) such thatclamp 608 aa can be disposed around drive hub 304 aa and IO device 100bb (e.g., around hub 150 bb) to resist separation of the IO device (and,more specifically, hub 150 bb, in this embodiment) from the driver (and,more specifically, drive hub 304 aa, in this embodiment), as shown inFIG. 29A.

In the embodiment shown, hub 150 bb of IO device 100 bb has across-section with a circular central portion and a projection 628 aaextending from the central portion in a direction away from a rotationalaxis of the drive hub, as shown. In this embodiment, clamp 608 aaincludes a slot 632 aa between opposing portions of the clamp such thatprojection 628 aa can be aligned with (disposed in) slot 632 aa toresist rotation of hub 150 bb relative to clamp 608 aa. In someembodiments, drive hub 304 aa can have a cross-section similar to thatof hub 150 bb (e.g., having a circular central portion and a projectionof the same size(s) as those of hub 150 bb), such that the projection ofdrive hub 304 aa can align with (disposed in) a second slot 636 aa ofclamp 608 aa to resist rotation of drive hub 304 aa relative to clamp608 aa. In the embodiment shown, drive hub 304 a is not configured toreceive a portion of IO device 100 bb (e.g., adjacent ends of the drivehub and IO device abut each other without overlapping longitudinally, asshown). As shown in FIG. 29A, drive hub 304 aa is configured to abut IOdevice 100 bb such that clamp 608 aa can be disposed around and incontact with drive hub 304 aa and IO device 100 bb to resist separationof the IO device from the drive hub.

FIGS. 30A-30C depict various views of a twenty-sixth embodiment 300 bbof the present couplers in combination with a powered driver 200 bb andan IO device 100 cc that is configured for obtaining a sample of boneand/or bone marrow (e.g., similar in some respects to IO devices 100 aand/or 100 b). In the embodiment shown, coupler 300 bb comprises a drivehub 304 bb having a first end 308 bb and a second end 312 bb. In thisembodiment, first end 308 bb of drive hub 304 bb includes a sidewall 640bb defining a recess 340 bb configured to receive a hub (e.g., first hub140 cc) of IO device 100 cc. In this embodiment, sidewall 640 bb has atleast one (e.g., two, as shown) slot 644 bb extending through thesidewall in communication with recess 340 bb. Clamp 608 bb (which issubstantially similar to clamp 608 aa described above) is configured tofit over sidewall 640 bb and slot 644 bb permits the sidewall to flexinwardly to clamp hub 140 cc. In the embodiment shown, hub 140 cc of IOdevice 100 cc has a cross-section with a circular central portion andprojections 628 bb extending from the central portion in a directionaway from a rotational axis of the drive hub, as shown. In thisembodiment, projections 628 bb can be aligned with (e.g., disposed in)slots 644 bb to resist rotation of hub 140 cc relative to drive hub 304bb. In this embodiment, the transverse dimension of drive hub 304 bb isgreater than the contracted transverse dimension of clamp 608 bb suchwhen clamp 608 bb is disposed around first end 308 bb of drive hub 304bb, clamp 608 bb will contact and apply a compressive force toprojections 628 bb (as well as to sidewall 640 bb) to resist separationof the IO device (and, more specifically, hub 140 cc, in thisembodiment) from the driver (and, more specifically, drive hub 304 bb,in this embodiment).

In the embodiment shown, second end 312 bb of drive hub 304 bb includessidewall 648 bb defining a recess 336 bb configured to receivedriveshaft 222 bb of driver 200 bb. In this embodiment, sidewall 648 bbhas at least one (e.g., two, as shown) slot 652 bb extending through thesidewall in communication with recess 336 bb. Coupler 300 bb alsocomprises a clamp 656 bb (which is substantially similar to clamp 608 aadescribed above) that is configured to fit over sidewall 648 bb and slot652 bb may permit the sidewall to flex inwardly to clamp hub 140 cc. Inthe embodiment shown, driveshaft 222 bb of driver 200 bb has across-section with a circular central portion and projections 660 bbextending from the central portion in a direction away from a rotationalaxis of the drive hub, as shown. In this embodiment, projections 660 bbcan be aligned with (disposed in) slots 652 bb to resist rotation ofdrive hub 304 bb relative to driveshaft 222 bb. In this embodiment, thetransverse dimension of driveshaft 222 bb is greater than the contractedtransverse dimension of clamp 656 bb such that when clamp 656 bb isdisposed around second end 312 bb of drive hub 304 bb, clamp 656 bb willcontact and apply a compressive force to projections 660 bb to resistseparation of drive hub 304 bb from driveshaft 222 b. Coupler 300 bbalso includes a recess 324 bb that is sized to receive a second hub (notshown, but similar to second hub 150 a of IO device 100 a).

FIGS. 31A-31D depict various views of a twenty-seventh embodiment 300 ccof the present couplers in combination with a powered driver 200 cc andan IO device 100 dd that is that is configured to provide access to aninterior of a bone (e.g., similar in some respects to IO device 100 c).In the embodiment shown, coupler 300 cc comprises a drive hub 304 cchaving a first end 308 cc and a second end 312 cc configured to becoupled in fixed relation to driveshaft 222 cc of driver 200 cc (e.g.,second end 312 cc is unitary with driveshaft 222 cc in the embodimentshown). In the embodiment shown, first end 308 aa includes a pluralityof movable prongs 664 cc configured to grasp a hub (e.g., second hub 150dd) of IO device 100 dd; and a collar 668 cc that is movably disposedaround drive hub 304 cc, as shown. In this embodiment, collar 668 cc ismovable between: (i) a first position (FIGS. 31B and 31C) in whichprongs 664 cc can move away from the rotational axis of the drive hub topermit IO device 100 dd to be inserted into or removed from the prongs,and (ii) a second position (FIG. 31D) in which collar 668 cc constrainsprongs 664 cc such that if hub 150 dd is disposed between prongs 664 cc,prongs 664 cc resist removal of the IO device from the plurality ofprongs. In some embodiments, collar 668 cc is biased toward the secondposition (e.g., by a spring (not shown) disposed between collar 668 ccand housing 210 cc of driver 200 cc). In the embodiment shown, hub 150dd of IO device 100 dd comprises a projection 456 cc with one or moredetents 452 cc that are configured to receive a portion of prongs 664cc, as shown in FIG. 31D. While not shown in FIGS. 31A-31D, otherembodiments can comprise a second plurality of prongs and a secondcollar at second end 312 cc to engage a driveshaft of a driver (e.g.,with corresponding detents).

FIGS. 32A-32C depict various views of a twenty-eighth embodiment 300 ddof the present couplers in combination with a powered driver 200 dd andan IO device 100 ee that is configured to provide access to an interiorof a bone (e.g., similar in some respects to IO device 100 c). In theembodiment shown, coupler 300 dd comprises a drive hub 304 dd having afirst end 308 dd and a second end 312 dd including a recess 336 ddconfigured to receive driveshaft 222 dd of driver 200 dd, with recess336 dd having a proximal end at second end 312 dd and a distal endcloser to first end 308 dd. In this embodiment, coupler 300 dd alsocomprises a ring 672 dd that comprises at least one of amagnetically-chargeable (e.g., iron) and a magnetically-attractivematerial (e.g., a permanent magnet). Ring 672 dd is disposed around aperimeter of recess 336 dd between the proximal and distal ends of therecess, as shown. In this embodiment, driver 200 dd also comprises aring 676 dd that comprises at least one of a magnetically-chargeable(e.g., iron) and a magnetically-attractive material (e.g., a permanentmagnet). Ring 676 dd is disposed around and coupled in fixed relation todriveshaft 222 dd, as shown. Ring 672 dd and ring 676 dd are configuredto be magnetically attracted to each other when driveshaft 222 dd isinserted into recess 336 dd (FIG. 32C) to resist separation of drive hub304 dd from driveshaft 222 dd. For example, ring 672 dd and ring 676 ddcan both comprise magnetically-attractive materials, or one can comprisea magnetically-attractive material and the other can comprise amagnetically-chargeable material. In this embodiment, first end 308 ddof drive hub 304 dd is configured to be coupled to an intraosseous (IO)device (e.g., to resist rotation of the IO device relative to the drivehub). For example, in the embodiment shown, drive hub 304 dd is unitarywith a portion of the hub assembly of the IO device (e.g., unitary withsecond hub 150 ee). In some embodiments, driveshaft 222 dd and/or recess336 dd have non-circular cross-sectional shapes (e.g., to resistrotation of drive hub 304 dd relative to driveshaft 222 dd). As shown,recess 336 dd and ring 672 dd are configured such that ring 672 dddefines a step within the recess between the proximal and distal ends ofthe recess.

FIGS. 33A-33B depict cutaway perspective and side cross-sectional views,respectively, of a twenty-ninth embodiment 300 ee of the presentcouplers in combination with a powered driver 200 ee and an IO device100 ff that is configured to provide access to an interior of a bone(e.g., similar in some respects to IO device 100 c). In the embodimentshown, coupler 300 ee comprises a drive hub 304 ee having a first end308 ee and a second end 312 ee including a recess 336 ee configured toreceive driveshaft 222 ee of driver 200 ee, with recess 336 ee having aproximal end at second end 312 ee and a distal end closer to first end308 ee. In this embodiment, coupler 300 ee also comprises a ring 672 eethat comprises at least one of a magnetically-chargeable (e.g., iron)and a magnetically-attractive material (e.g., a permanent magnet). Ring672 ee is disposed around a perimeter of recess 336 ee between theproximal and distal ends of the recess, as shown. In this embodiment,driver 200 ee also comprises an element 680 ee that comprises at leastone of a magnetically-chargeable (e.g., iron) and amagnetically-attractive material (e.g., a permanent magnet). As shown,element 680 ee is disposed within the perimeter of driveshaft 222 ee andspaced apart from the distal end 224 ee of the driveshaft, as shown.Ring 672 ee and element 680 ee are configured to be magneticallyattracted to each other when driveshaft 222 ee is inserted into recess336 ee (FIG. 33B) to resist separation of drive hub 304 ee fromdriveshaft 222 ee. For example, ring 672 ee and element 680 ee can bothcomprise magnetically-attractive materials, or one can comprise amagnetically-attractive material and the other can comprise amagnetically-chargeable material. In this embodiment, first end 308 eeof drive hub 304 ee is configured to be coupled to an intraosseous (IO)device (e.g., to resist rotation of the IO device relative to the drivehub). For example, in the embodiment shown, drive hub 304 ee is unitarywith a portion of the hub assembly of the IO device (e.g., unitary withsecond hub 150 ff). In some embodiments, driveshaft 222 ee and/or recess336 ee have non-circular cross-sectional shapes (e.g., to resistrotation of drive hub 304 ee relative to driveshaft 222 ee).

FIGS. 34A-34C depict various views of a thirtieth embodiment 300 ff ofthe present couplers in combination with a powered driver 200 ff and anIO device 100 gg that is configured for obtaining a sample of boneand/or bone marrow (e.g., similar in some respects to IO devices 100 aand/or 100 b). In the embodiment shown, coupler 300 ff comprises a drivehub 304 ff having a first end 308 ff and a second end 312 ff including arecess 336 ff configured to receive driveshaft 222 ff of driver 200 ff,with recess 336 ff having a proximal end at second end 312 ff and adistal end closer to first end 308 ff. In this embodiment, coupler 300ff also comprises a ring 672 ff that comprises at least one of amagnetically-chargeable (e.g., iron) and a magnetically-attractivematerial (e.g., a permanent magnet). Ring 672 ff is disposed around aperimeter of recess 336 ff between the proximal and distal ends of therecess, as shown. In this embodiment, driver 200 ff also comprises aring 676 ff that comprises at least one of a magnetically-chargeable(e.g., iron) and a magnetically-attractive material (e.g., a permanentmagnet). Ring 676 ff is disposed around and coupled in fixed relation todriveshaft 222 ff, as shown. Ring 672 ff and ring 676 ff are configuredto be magnetically attracted to each other when driveshaft 222 ff isinserted into recess 336 ff (FIG. 34C) to resist separation of drive hub304 ff from driveshaft 222 ff. For example, ring 672 ff and ring 676 ffcan both comprise magnetically-attractive materials, or one can comprisea magnetically-attractive material and the other can comprise amagnetically-chargeable material. In some embodiments, driveshaft 222 ffand/or recess 336 ff have non-circular cross-sectional shapes (e.g., toresist rotation of drive hub 304 ff relative to driveshaft 222 ff). Asshown, recess 336 ff and ring 672 ff are configured such that ring 672ff defines a step within the recess between the proximal and distal endsof the recess. Further, in this embodiment driveshaft 222 ff comprisesan enlarged cap member 223 ff (on which ring 672 ff is disposed) thatcan comprise a resilient material (e.g., a resilient polymer) to furtherfacilitate insertion of driveshaft 222 ff into recess 336 ff.

Coupler 300 ff differs from coupler 300 dd, for example, in that firstend 308 ff includes a recess 340 ff configured to receive a hub (e.g.,first hub 140 gg) of IO device 100 gg, with recess 340 ff having adistal end at first end 308 ff and a proximal end closer to second end312 ff In this embodiment, coupler 300 ff also comprises a ring 684 ffthat comprises at least one of a magnetically-chargeable (e.g., iron)and a magnetically-attractive material (e.g., a permanent magnet). Ring684 ff is disposed around a perimeter of recess 340 ff between theproximal and distal ends of the recess, as shown. In this embodiment,driver 200 ff also comprises a ring 688 ff that comprises at least oneof a magnetically-chargeable (e.g., iron) and a magnetically-attractivematerial (e.g., a permanent magnet). Ring 688 ff is disposed around andcoupled in fixed relation to hub 140 gg, as shown. Ring 684 ff and ring680 ff are configured to be magnetically attracted to each other whenhub 140 gg is inserted into recess 340 ff (FIG. 34C) to resistseparation of hub 140 gg from drive hub 304 ff. For example, ring 684 ffand ring 684 ff can both comprise magnetically-attractive materials, orone can comprise a magnetically-attractive material and the other cancomprise a magnetically-chargeable material. In some embodiments, hub140 gg and recess 340 ff have non-circular cross-sectional shapes (e.g.,to resist rotation of hub 140 gg relative to drive hub 304 ff). Asshown, recess 340 ff and ring 684 ff are configured such that ring 684ff defines a step within the recess between the proximal and distal endsof the recess. Coupler 300 ff also includes a recess 324 ff that issized to receive a second hub (not shown, but similar to second hub 150a of IO device 100 a).

FIGS. 35A-35C depict various views of a thirty-first embodiment 300 ggof the present couplers in combination with a powered driver 200 gg andan IO device 100 hh that is configured for obtaining a sample of boneand/or bone marrow (e.g., similar in some respects to IO devices 100 aand/or 100 b). In the embodiment shown, coupler 300 gg comprises a drivehub 304 gg having a first end 308 gg and a second end 312 gg including arecess 336 gg configured to receive driveshaft 222 gg of driver 200 gg,with recess 336 gg having a proximal end at second end 312 gg and adistal end closer to first end 308 gg. In this embodiment, coupler 300gg also comprises a ring 672 gg that comprises at least one of amagnetically-chargeable (e.g., iron) and a magnetically-attractivematerial (e.g., a permanent magnet). Ring 672 gg is disposed around aperimeter of recess 336 gg between the proximal and distal ends of therecess, as shown. In this embodiment, driver 200 ff also comprises atleast one (e.g., two, as shown) element 680 gg that comprises at leastone of a magnetically-chargeable (e.g., iron) and amagnetically-attractive material (e.g., a permanent magnet). As shown,elements 680 gg are disposed within the perimeter of driveshaft 222 ggand spaced apart from the distal end 224 gg of the driveshaft, as shown.Ring 672 gg and elements 680 gg are configured to be magneticallyattracted to each other when driveshaft 222 ff is inserted into recess336 ff (FIG. 35B) to resist separation of drive hub 304 gg fromdriveshaft 222 gg. For example, ring 672 gg and element 680 gg can bothcomprise magnetically-attractive materials, or one can comprise amagnetically-attractive material and the other can comprise amagnetically-chargeable material. In some embodiments, driveshaft 222 ggand/or recess 336 gg have non-circular cross-sectional shapes (e.g., toresist rotation of drive hub 304 gg relative to driveshaft 222 gg).Further, in this embodiment driveshaft 222 gg comprises an enlarged capmember 223 gg (in which elements 680 gg are disposed) that can comprisea resilient material (e.g., a resilient polymer) to further facilitateinsertion of driveshaft 222 gg into recess 336 gg.

Coupler 300 gg differs from coupler 300 ee, for example, in that firstend 308 gg includes a recess 340 gg configured to receive a hub (e.g.,first hub 140 hh) of IO device 100 hh, with recess 340 gg having adistal end at first end 308 gg and a proximal end closer to second end312 gg. In this embodiment, coupler 300 gg also comprises a ring 684 ggthat comprises at least one of a magnetically-chargeable (e.g., iron)and a magnetically-attractive material (e.g., a permanent magnet). Ring684 gg is disposed around a perimeter of recess 340 gg between theproximal and distal ends of the recess, as shown. In this embodiment,driver 200 gg also comprises at least one (e.g., two, as shown) element692 gg that comprises at least one of a magnetically-chargeable (e.g.,iron) and a magnetically-attractive material (e.g., a permanent magnet).As shown, elements 692 gg are disposed within the perimeter of hub 140hh. Ring 684 gg and elements 692 gg are configured to be magneticallyattracted to each other when driveshaft 222 gg is inserted into recess340 gg (FIG. 35B) to resist separation of hub 140 hh from drive hub 304gg. For example, ring 684 gg and elements 692 gg can both comprisemagnetically-attractive materials, or one can comprise amagnetically-attractive material and the other can comprise amagnetically-chargeable material. In some embodiments, hub 140 hh and/orrecess 340 gg have non-circular cross-sectional shapes (e.g., to resistrotation of hub 140 hh relative to drive hub 304 gg). Coupler 300 ggalso includes a recess 324 gg that is sized to receive a second hub (notshown, but similar to second hub 150 a of IO device 100 a).

The above specification and examples provide a complete description ofthe structure and use of exemplary embodiments. Although certainembodiments have been described above with a certain degree ofparticularity, or with reference to one or more individual embodiments,those skilled in the art could make numerous alterations to thedisclosed embodiments without departing from the scope of thisinvention. As such, the various illustrative embodiments of the presentdevices are not intended to be limited to the particular formsdisclosed. Rather, they include all modifications and alternativesfalling within the scope of the claims, and embodiments other than theone shown may include some or all of the features of the depictedembodiment. For example, components may be combined as a unitarystructure, and/or connections may be substituted (e.g., threads may besubstituted with press-fittings or welds). Further, where appropriate,aspects of any of the examples described above may be combined withaspects of any of the other examples described to form further exampleshaving comparable or different properties and addressing the same ordifferent problems. Similarly, it will be understood that the benefitsand advantages described above may relate to one embodiment or mayrelate to several embodiments.

The claims are not intended to include, and should not be interpreted toinclude, means-plus- or step-plus-function limitations, unless such alimitation is explicitly recited in a given claim using the phrase(s)“means for” or “step for,” respectively.

What is claimed is:
 1. A coupler comprising: a drive hub having a firstend and a second end including a recess configured to receive adriveshaft of a driver; where the first end of the drive hub isconfigured to be coupled to an intraosseous (IO) device to resistrotation of the IO device relative to the drive hub; and where thesecond end of the drive hub is configured such that if a driveshaft isinserted into the recess, an interference fit between the drive hub andthe driveshaft will resist rotation of the drive hub relative to thedriveshaft.
 2. The coupler of claim 1, where the recess has a circularcross-sectional shape.
 3. The coupler of claim 1, where the recess isdefined by a cylindrical wall.
 4. The coupler of claim 3, where thesecond end further includes a second recess surrounding at least aportion of the cylindrical wall.
 5. The coupler of claim 1, where thesecond end of the hub includes a plurality of tabs extending into therecess, the plurality of tabs being configured to deform if thedriveshaft is inserted into the recess.
 6. The coupler of claim 5, wherethe plurality of tabs each has a triangular cross-sectional shape. 7.The coupler of claim 1, where the recess has a circular central portionand one or more peripheral portions extending outwardly from thecircular central portion.
 8. The coupler of claim 7, where the pluralityof tabs extend into the peripheral portions of the openings.
 9. Thecoupler of claim 1, where the first end of the drive hub includes arecess and is configured such that if a hub of an IO device is insertedinto the recess, an interference fit between the drive hub and the IOdevice will resist rotation of the IO device relative to the drive hub.10. A coupler comprising: a drive hub having a first end and a secondend configured to be coupled in fixed relation to a driveshaft of adriver; where the first end of the drive hub has a recess configured toreceive a portion of an intraosseous (IO) device; and where the firstend of the drive hub is configured such that if a portion of the IOdevice is inserted into the recess, an interference fit between thedrive hub and the IO device will resist rotation of the IO devicerelative to the drive hub.
 11. The coupler of claim 10, where the recesshas a circular cross-sectional shape.
 12. The coupler of claim 10, wherethe recess is defined by a cylindrical wall.
 13. The coupler of claim12, where the first end further includes a second recess surrounding atleast a portion of the cylindrical wall.
 14. The coupler of claim 10,where the first end of the hub includes a plurality of tabs extendinginto the recess, the plurality of tabs configured to deform if thedriveshaft is inserted into the recess.
 15. The coupler of claim 14,where the plurality of tabs each has a triangular cross-sectional shape.16. The coupler of claim 10, where the recess has a circular centralportion and one or more peripheral portions extending outwardly from thecircular central portion.
 17. The coupler of claim 16, where theplurality of tabs extend into the peripheral portions of the openings.18. The coupler of claim 10, where the second end of the drive hubincludes a recess and is configured such that if the driveshaft isinserted into the recess, an interference fit between the drive hub andthe driveshaft will resist rotation of the drive hub relative to thedriveshaft.
 19. A coupler comprising: a drive hub having a first end anda second end including a recess configured to receive a driveshaft of adriver; and an adhesive disposed in the recess and configured to adhereto a driveshaft inserted into the recess; where the first end of thedrive hub is configured to be coupled to an intraosseous (IO) device toresist rotation of the IO device relative to the drive hub; and wherethe recess has a cross-sectional shape corresponding to thecross-sectional shape of the driveshaft such that if the driveshaft isinserted into the second recess, the drive hub will resist rotatingrelative to the driveshaft.
 20. The coupler of claim 19, where: thefirst end of the drive hub includes a second recess configured toreceive a hub of an IO device; the second recess has a cross-sectionalshape corresponding to a cross-sectional shape of the hub of the IOdevice such that if the portion of the IO device is inserted into therecess, the drive hub will resist rotation of the IO device relative tothe drive hub; and the coupler further comprises a second adhesivedisposed in the second recess and configured to adhere to an IO deviceinserted into the second recess.